Hindustan Aircraft designed and built the first indigenous Indian aircraft, the Hindustan HT-2 two-seat trainer. The HT-2 is of stressed all-metal construction, with semi-monocoque fuselage and two-spar wing. All covering is metal. The fixed oleo-strut undercarriage is attached to the front wing spar, and features hydraulic brakes. Full equipment includes an electric starter and full dual controls and instruments.
First flying on 13 August 1951, the prototype was registered VT-DFW. The second aircraft, VT-DFY first flew on 19 February 1952 and had the shape of the fin and rudder altered considerably to increase the chord. This was retained on the production aircraft.
The HT-2 received the Government of India’s first Type Certificate, issued on 20 December 1952. By then, several military machines were flying, as well as the prototypes.
The first production aircraft were delivered to the Indian Air Force towards the end of January 1953.
The HT-2 was produced for the Indian Air Force and civilian flying clubs. The HT-2 was a two-seat primary trainer that went on to serve with both the Indian Air Force and Indian Navy, replacing the de Havilland Tiger Moth as the nation’s introductory training aircraft. Pilots affectionately nicknamed the HT-2 the Dalda Tin, referencing its resemblance to a tin of Dalda, a well-known brand of vegetable oil in India.
First prototype in flight
The type entered service in 1953, powered by a 155-horsepower Cirrus Major III four-cylinder inverted inline engine, the HT-2 could cruise at 115 mph and reach a top speed of 130 mph. Its stall speed was relatively high for a single-engine trainer at 52 mph. With a range of 300 nautical miles and an endurance of three hours and thirty minutes, the aircraft was well-suited for short training hops as well as cross-country flights.
Department of Aerospace Engineering at Indian Institute of Science, Bangalore.
Beyond India, twelve HT-2s served with the Ghana Air Force from 1959 to 1974. The aircraft was also a favorite among civilian flight schools throughout India. Over the course of its production run, HAL built a total of 172 HT-2 airframes. The last examples were retired from active service in 1990. Today, no airworthy HT-2s are known to exist, although several preserved examples can be found on display in aviation museums across India.
Engine: Blackburn Cirrus Major III, 155 hp Wingspan: 35 ft 2 in Length: 25 ft 2.5 in Height: 8 ft 11 in Empty weight: 1600 lb Loaded weight: 2240 lb Useful load: 640 lb Fuel capacity: 26 Imp.Gal Max speed SL: 130 mph Cruise: 115 mph ROC: 800 fpm Service ceiling: 14,500 ft Range: 350 mi Endurance: 3.5 hr Seats: 2
1962: 31 Chittaranjan Ave, Calcutta 12, India Aeronautical Services manufactured 56 Ashvini-II and 35 Rohini-I training sailplanes for the Indian Civil Aviation Department 56. Aeronautical Services also built many IT-G3 single seat intermediate traing gliders based on the Grunau Baby.
Hindustan Aircraft Ltd. (formed in 1940) was amalgamated with Aeronautics India Ltd. (formed 1963) to establish Hindustan Aeronautics Ltd. in October 1964. Hindustan Aircraft designed and built the first indigenous Indian aircraft, the Hindustan HT-2 two-seat trainer, which first flew in 1951 and was produced for the Indian Air Force and civilian flying clubs. The HUL-26 Pushpak high-wing lightplane, based on the American Aeronca Chief, entered production in 1959, the HAOP-27 Krishak derivation being manufactured as a liaison aircraft for the Indian Air Force and Army. Deliveries of the HAL HJT-16 Kiran two-seat jet trainer began in 1966. The HF-24 Marut single-seat fighter was designed by a team led by Kurt Tank, and deliveries of the Ajeet lightweight jet fighter, developed from the Folland/ Hawker Siddeley Gnat which HAL license-produced, began to the Indian Air Force in 1976. HAL also built the HA-31 Basant agricultural aircraft. Assembly of Soviet MiG-21 fighters began 1966, with full manufacture from 1970 (production ended). Assembly/ production of Soviet MiG-27M began 1984 (production ended 1994). Assembly/production of the SEPECAT Jaguar International as the Shamsher (first flown March 1982) ended 1998. HPT-32 Deepak two-seat ab initio and basic piston-engined trainer first flown 1977; 134 built for Indian Air Force and eight for Navy to replace HT-2s. Licence-manufactured SA-315B Lama and SA-316B Alouette III helicopters as Cheetah and Chetak respectively up to 1998, when production gave way to the indigenously developed Advanced Light Helicopter (first flown August 1992). HAL responsible for manufacture of the ADA Light Combat Aircraft. New HJT-36 turbofan trainer and HTT- 38 turboprop trainer announced for development in 1998. Continuing work on AWACS aircraft. Other work includes overhaul of all Indian Air Force aircraft, together with component manufacture in connection with international aircraft programs and India’s space research program.
The Hillman Hornet, first flown in 1978, was top rotorcraft award winner at Oshkosh ‘78 and received the Best Helicopter Design honors at the Popular Rotor-craft Convention in Rockford, Illinois. Developed in 1979, in 1980 a Turbo Hornet was in production. Standard features include a comfortable cockpit for two, excellent visibility, room for a variety of avionics and dual controls. Flight performance has been favorably compared with that of the Hughes 300. The Hornet is available in kit form for owner assembly for $29,950 under one of several factory-supervised programs. Assembly assistance is available at the factory in addition to flight training. Optional features now under development are floats, cargo hook, fibreglass tailboom shroud, doors and turbo-charging.
Gross Wt. 1400 lb. Empty Wt. 800 lb Fuel capacity 22 USG Rotor span 25 ft 5 in Length 21 ft 2 in Engine 150-hp Lycoming Top speed 100 mph. Cruise 90 mph. Climb rate 1000 fpm. Ceiling 12,000 ft Range 200 miles
After Douglas Hillman developed WankelBee helicopter with rotary combustion engine (first flown 1975) and two-seat Hornet (first flown 1978). 1980: Hillman Helicopters Inc., Box 1411, Scottsdale, AZ 85252, USA. Hillman Helicopter designed Model 360 as three-seat utility helicopter of very modern design which first flew 1981.
Early in 1952, Hiller approached the Navy about authorizing construction of an evaluation quantity of Hornets. The proposal was accepted because it was felt that a revised Hornet might meet a Marine Corps requirement for an ultralight flying vehicle. By summer a fixed-price contract had been negotiated for delivery of five units, three to go to the Navy as the HOE-1. Impressed by the simplicity of the original HJ-1, the Army asked to take the remaining two (serials 53-4663 and -4664) under the designation YH-32. At the end of 1954, Army officials ordered a dozen more Hornets (55-4963 through -4974), and Hiller’s own test and demonstration requirements brought the total of second-generation Hornets to twenty-five, including the three ULV gunships. The twelve aircraft were all delivered by late 1956. This evaluation quantity of HOEs and YH-32s marked the first production of tip-jet-powered helicopters in history, and the first procurement of such vehicles by U.S. military services.
Although the new military helicopter shared the name and designation of the original HJ-1 “Hornet”, it was an all-new machine with no commonality. It had lightweight skids, and it had rudder pedals controlling a single-blade tail rotor. While not needed to offset torque, the tail rotor – which furnished crisper yaw control than was provided by the earlier Hornet’s rudder – helped during autorotation and permitted rapid sideways flight as required by increasingly stringent military control requirements.
The HOE-1/H-32 was designed by both Bob Anderson and James B. Edwards, the vice president of engineering, who had come to Hiller in January 1952 from Douglas Aircraft. The HJ-1 suffered a growth in size and weight. A larger cockpit, fiberglass body and tail boom (the first structural use of fiberglass in aircraft construction), and other changes raised the empty weight from the original Hornet’s 160kg to 240kg, and the gross weight climbed to 480kg. As a result, the service ceiling fell from 3350m to 2100m. Even with 200 litres of fuel, the craft’s range shrank from 65km to 45km, its maximum powered endurance at economy cruise being roughly thirty minutes.
The joint military program by the Army and Navy had many extra-contractual changes that – including the dual certification programs – eventually consumed more than a million dollars of Hiller resources.
The first of the HOE/H-32 series flew in September 1953, with deliveries to commence the following spring. The services did not receive them until the end of 1954, because these machines had been procured on a “certification specification” basis rather than on the standard “mil. spec.” basis, and civil certification of the helicopter and its engine would take time, as both were new to the experience of the CAA. The 8RJ2B ramjet engine was a refined and uprated version of the unit Hiller had developed in 1949. Now eight inches in diameter and weighing 5.7kg, it produced the equivalent of 45hp. Manufactured by Ryan in San Diego under license from Hiller, the 8RJ2B was made out of lnconel X, a high-nickel alloy. Because Inconel X corrodes on contact with lead – then commonly found in automotive gasoline, which was a likely fuel for this engine – the engine’s interior was coated with a protective ceramic material. By August, the 8RJ2B had logged 559 hours in the air, 2104 hours on the whirlstand, and 1545 hours in free airstream static tests. Its early teething troubles had been completely solved, even the once nagging problem of flameouts. If flameouts should occur, the engine now reignited itself so quickly that the pilot never perceived the problem. Another selling point was the remarkable portability and simplicity of the 8RJ2B. An untrained person could change a Hiller Hornet’s engine in just three minutes with a screwdriver.
Ramjet testing on the ground included static duration runs, which were a sore point with residents of Belle Haven and East Palo Alto. One test in March 1953 lasted 200 hours, while another the following February ran for 150 hours. At night an inversion would often form over the entire San Francisco Bay area, causing the bam-bam-bam of the whirling ramjets to skip over much of the local area and bounce squarely into the fashionable Atherton and Menio Park neighborhoods. Residents often telephoning the plant at Palo Alto to complain. The problem was significantly reduced in the spring of 1954 by construction of a circular barrier 5.5m high and 12m in diameter, which was designed to muffle jet engine noise. During the last days of ramjet certification in 1954, several overspeed runs were conducted on the whirlstand. At peak rpm, when the tip jet was subjected to as much as 14000 Gs (boosting its “weight” to some 80300kg), supporting bolts sheared and the 8RJ2B shot away through protective walls, acoustical barriers, and property fences before coming to rest some 150m from the test site. The test stand also departed the area, flying off toward San Francisco Bay. It was later recovered from nearby mud flats. The only known structural failure of a Hiller tip-power rotor, this test far exceeded expectations and overwhelmingly satisfied the stringent certification requirements. On October 28, 1954, the CAA awarded Hiller’s 8RJ2B engine Type Certificate No. 280, officially approving it for commercial production and sale should Hiller so desire.
Parallel certification for the “Hornet” helicopter was not granted. The reason was the cold drag problem associated with autorotation, as with the earlier HJ-1. The new military Hornets descended steeply at almost 18m/s, but their massive rotors stored so much energy that landings were simple after one became accustomed to the high sink rate. Hiller test pilot and marketing executive Robert Boughton found that whereas one would begin to flare 15 to 18m above the ground in a normal helicopter, the “Hornet” demanded that one begin pulling up on the collective a full two to three hundred feet off the ground. Enough inertia was stored in the tip engines to permit the pilot to touch down, rise into the air again, and land a second time. A solution to the unacceptably high sink rate was proposed to the military during development of the H-32 and HOE. The company suggested that the flameholders in the mouths of the ramjets be modified to function like controllable shutters. During autorotation, they could simply rotate shut to close off air-flow through the engine and greatly reduce cold drag. If one engine failed, the “Hornet” could be flown some distance to a safe landing, although it could not maintain altitude. An automatic low-fuel power reduction further enhanced safety by alerting the pilot to land while sufficient fuel remained to do so under power. Still, with range so limited and the possibility of fuel starvation so great, flameholder shutters were clearly a desirable feature. The military declined because its strict acceptance standards made no provision for such devices. Without them, the Hornet’s autorotation proved unacceptable to the CAA, which otherwise found the diminutive craft satisfactory. Civil certification was accordingly denied. Failure to achieve this production license removed any possibility of Hornets reaching the private market, although it is doubtful that Hiller would have chosen to market a civil version in any event.
YH-32
On a warm day the Hornet could barely hover over a metre above the ground with two people and a full fuel load. The Hornet was able to run on a wide variety of fuels, but the fuel tank held only enough for 25 minutes flying or 65km range. The rotor needed to be spun to 50 rpm by a small motor before the ramjets would start. Normal operating speed was 550 rpm. Fuel pressure was then built up, fuel flow valves were opened, and the starter button was depressed to fire a spark plug in each ramjet. Ninety seconds later, the Hornet’s rotor reached 450-500 rpm and away it flew. Pilots who had the chance to try it out reported generally pleasant and forgiving characteristics.
The museum owning the only remaining flyable example of the 17 Hornets built received complaints from neighbours a mile and a half away when they last flew it.
HOE-1 Engine: 2 x 8RJ2B ramjets, 17kg / 31 lb of thrust each Main rotor diameter: 7.0m / 23 ft Fuselage length: 3.45m / 12 ft. 8 in Height: 2.44m Take-off weight: 487kg Loaded weight: 1,200 lb. Empty weight: 239kg Max speed: 129km/h / 80 m.p.h Cruising speed: 111km/h Service ceiling: 3500m / 12,000 ft Range: 450km Typical range: 31 miles at 70 m.p.h. with full load. Seats: 2
Originally intended for the civil market with a price as little as $5,000, the Hiller Hornet was a tiny helicopter powered by ramjet engines mounted on the rotor tips. Although Hiller never realized the long-held dream of flying crane production for want of government sponsorship, this program did have conspicuous successes. The comprehensive body of research it generated has paved the way for such helicopters to be built in the future, eliminating every real or imagined obstacle to their construction. This program also fostered the development of two generations of the Hiller HJ-1 Hornet. The first of these generations began with the construction of three HJ-1s in Palo Alto in 1950. Just 2.1m high, weighing 400kg fully loaded, and topped with 7m-diameter rotors, these machines were far less complex than conventional helicopters. Only their Rotormatic paddles revealed them to be Hiller machines. Frank Peterson flew the first Hiller HJ-1 “Hornet” in August day in 1950. The two-place craft was of simple construction, consisting mainly of a reinforced steel tube framework overlaid with a skin of fiberglass and plastic laminate. The Hornet was powered by two Hiller 8RJ2B ramjets, one fixed to the end of each main rotor blade, with an auxiliary one horsepower gasoline engine being used to spin the rotor blades up to the 50 rpm required prior to ignition of the ramjets. The HJ-1 “Hornet” generated substantial public interest when unveiled by Hiller in February 1951. At that time it was announced that the company might offer them for sale at less than $5,000 each. Its top speed was 130km/h, cruise was 110km/h, the service ceiling was 3350m, and the initial rate of climb was 5.6m/s. The only drawback was range, as a fully loaded HJ-1 could travel only a little under 65km. The HJ-1 was stable for a small helicopter because of its Rotormatic paddles and high-inertia rotor. The docile manners ended at autorotation. Whereas conventional helicopters autorotate at 9m/s or so, the Hiller “Hornet” plummeted at 15m/s, because the intakes of its ramjets retarded rotor windmilling. Hiller’s aeronautical engineers christened this aerodynamic braking “cold drag”. However slowly it turned during autorotation, the rotor – with the weight of ramjets at its tips – had plenty of accumulated kinetic energy left to trade for lift when the time came. One merely needed skill, nerve, and fast reflexes to know when to haul up on the collective lever. Hiller Test Pilot Bruce Jones was the first person to autorotate a tip-powered helicopter. Ground observers stood aghast as he hurtled downward in the HJ-1, came to a radical flare in the nick of time, and settled to the ground. With a mix of relief and anger, Hiller’s non-pilot contracts manager ran up to the Hornet, shouting that the craft was not insured. “Listen,” the pilot replied hotly, steadying himself on rubbery legs. “I’m lucky to be alive! The aircraft was falling at 15m/s and I was falling at 10, and I barely caught up with the controls to land the damn thing!” Jones, a veteran World War II flier and a former Bell helicopter demonstration pilot, soon became the undisputed master of Hornet autorotations. An argument arose on the Hiller flight line one summer day in 1951 over what accuracy, if any, was possible during “deadstick” landings. Jones settled the issue once and for all by autorotating from 900m to land within 15m of dead center of the Hiller apron. With no torque to counter, the “Hornet” dispensed with a tail rotor in favor of a simple airplane-style rudder canted to take advantage of rotor downwash. Pedals were likewise eliminated; side-to-side movement of the collective lever worked the rudder to provide yaw control. An overhead cyclic stick provided lateral and longitudinal control as in the early model 360. On the touchy subject of noise, Hiller publicity releases optimistically stated that “the Hornet’s sound range compares favorably with that of a conventional-powered helicopter.” The “Hornet” had just two controls (cyclic and collective-cum-rudder) and tachometer, fuel flow gauge, airspeed indicator, altimeter, and starter button on its instrument panel. The Korean War preempted plans to market the HJ-1. Viewing its rapidly expanding backlog of military helicopter orders, and an uncertain public demand for the HJ-1, Hiller Helicopters announced in September 1951 that plans for marketing a civil version of the Hornet had been indefinitely deferred.
A prototype in the VTOL arena was the 33,000 lb Hiller X-18 tilt-wing convertiplane. The X-18 took to the air for the first time in November 1959, and in overall concept was configured as a transport type. Power was provided by two 5850-shp (4362-kW) Allison T40-A-14 turboshafts driving the two contra-rotating propeller/rotor units located one on each wing, and a 3400-lb (1542-kg) thrust J34 turbojet providing exhaust gases to a tail-mounted thrust diverter used for longitudinal control in vertical flight.
Stanley Hiller Jr designed the Model 360 which has enjoyed considerable commercial success since its first flight in 1948. It was derived from the UH-5 which had proved very unstable during trials and had subsequently been fitted with a new stability system patented as the Hiller ‘Rotormatic’. It entailed fitting the two-blade rotor with two small paddles which acted as a control rotor and were also connected to a hanging stick. This servo ‘paddle control’ system tilts the rotor head and actuates the cyclic pitch control. The Hiller 360 received its FAA (Federal Aviation Administration) approval in October 1948 and a year later a production model designated Model 12 made the first transcontinental helicopter flight across the USA. At that time it still had an open cockpit, and the 178hp Franklin 6V4-178-B33 was in an open engine bay.
Known as the Hiller UH-12 as Hiller had become part of United Helicopters, the Hiller UH-12, incorporating a two-bladed main rotor and a two-bladed tail rotor on an upswept boom. The UH-12 had a framed ‘bubble’-type cabin, no fuselage structure around the engine, skid undercarriage and a 175hp Franklin 6V4-178-B33 engine. Maximum takeoff weight was 1015kg.
The UH-12A Raven production two-seat UH-12 with collective pitch ballast system and wooden rotor blades for civil and military customers had a takeoff gross weight of 1082kg. With an uprated engine and new UH-12A rotor blades, it was purchased by the US Army and Navy for battlefield evacuation and observation tasks, with the designation H-23 Raven, whilst the Navy ordered the same basic model as the HTE-1 for training.
The commercial UH-12A to UH-12D became the OH-23A to OH-23D Raven respectively for service with the US Army, and the US Navy acquired UH-12As as HTE-1 and HTE-2.
HTE-2
The UH-12A successor, the H-23B, powered by a 200-210hp Franklin engine, was the first version used by the US Army as a trainer. 216 were assigned to the Primary Flying School at Fort Walters and another 237 were used for various tasks. The Hiller UH-12 was the US Army’s primary trainer until 1965. The UH-12B (and as the HT Mk.1 for the Royal Navy) normally had skid or flotation gear, but a wheeled undercarriage was fitted to a batch ordered by the US Navy (the HTE-2).
In 1955 the UH-12C, was basically a UH-1B. It retained the 200hp Franklin engine, but had all-metal rotor blades and a “goldfish bowl” cockpit canopy and three seats. From 1956, 145 were delivered to the US Army as the H-23C.
UH-12C
A purely military version, the UH-12D / OH-12D, flew on 3 April 1956 and 483 went to the US Army. The Franklin engine had been replaced by the more powerful 320hp Lycoming VO-540, and the transmission had also been changed to increase the service life of the helicopter.
The commonest version was the UH-12E which had a more powerful 305hp Textron Lycoming VO-540-A1A engine. The US Army replaced nearly all the OH-23Ds by Hiller 12Es, designated OH-23G 3-seat dual control trainer. In 1960 the Model E4 was developed from the Hiller 12E, with a longer cabin to seat four and an anhedral stabilizer on the tail boom. Twenty-two of these were acquired by the US Army as the OH-23F, for geodetic research.
Hiller UH-12E ZK-HFG
In 1963 the US Army was buying 137 more Hiller OH-23 observation helicopters to meet its requirements until a five-way competition for a light helicopter was decided at Ft. Rucker, Alabama. In 1963 the British navy was adding seven UH-12E to the 14 bought in 1962. The Royal Navy used its 12E’s to train fleet pilots at Culdrose Naval Air Station in Cornwall. They were fitted for instrument flying. 12E were also in use with Canada’s army and air force, known as CH-112.
The UH-12EL was a UH-12E retro-fitted with Ham-Standard rotor stability augmentation system, stainless steel rotor blades and 1400kg TOGW. UH-12E3 was the revised designation for Hiller Aircraft Corp production UH-12E with 3 seats, and UH-12E3T the Hiller Aircraft Corp UH-12ET. The UH-12E4 featured inverted rear tail planes and lengthened cabin to accommodate pilot plus rear bench seat for 3 pax. All new helicopters now have these features and they can be retrofitted on Model 12Es. Designated UH-12E4T when fitted with Soloy conversion to 400shp Allison 250-C20B turboshaft. This engine conversion was jointly developed with Soloy Conversions of Chehalis, Washington who began work on it in 1976.
The UH-12ET was the UH-12E fitted with Soloy conversion to 400shp Allison 250-C20B turboshaft. UH-12E5 was the UH-12E4 fitted with five seats and 340hp Textron Lycoming VO-540 piston engine. A prototype was flown but no further development was undertaken. The Korean War gave an added impetus to improvements and when the Hiller 12E appeared in 1959 it came either as the L3 with a 305hp Lycoming VO-540-C2A or as the SL3 with a supercharged 315hp TIVO-540-A2A engine. The UH-12SL was the UH-12E with supercharged Textron Lycoming TIVO-540 engine and ‘L’ series rotor head with gyro-controlled stability augmentation system. UH-12L was UH-12SL with unsupercharged VO-540 engine.
Civil versions with uprated powerplant included the UH-12E variants suffixed L3, L4, SL3 and SL4. The last civil variant, which appeared in 1963, was the Hiller 12L4 which was also used as a test-bed for a PT6 turbine, but the project was taken no further. Total sales of the Hiller 12E family exceeded 2000. Over 1,600 UH-12s went to the US Army and were used in Korea and Vietnam. At the height of UH-12/OH-23 production Hiller was taken over by the Fairchild Corporation, but in 1973 a new company, Hiller Aviation, acquired design rights and production tooling for the UH-12E, and for some years provided support for the world-wide fleet of UH-12 variants. UH-12E5T was a proposed turbine-powered UH-12E5 with Allison 250-C20B. Not built. UH-12J-3 was an unofficial designation for Soloy-converted UH-12E. UH-12SL4 was the UH-12L with the E4 four-seat cabin.
The Canadian army acquired OH-23Gs which it operated with the designation CH-112 Nomad, and the Royal Navy used a number of ex-US Navy HTE-2s under the designation Hiller HT.Mk 2. In April 1984 Hiller became a subsidiary of Rogerson Aircraft of Port Angeles, Washington. Renamed Hiller Helicopters and later Rogerson Helicopters, the company, now known as Rogerson Hiller, relaunched the piston-engined UH-12E in 1991 as the Hauler, and a number have been exported. The company is also proposing the Allison turbine-powered UH-12ET development for the US Army’s NHT (New Training Helicopter) requirement. The Model 12 has the usual equipment for helicopter safety and civil work, but can also be fitted with a night-lighting kit, a 454kg capacity cargo hook, twin heavy duty cargo racks, and auxiliary fuel tanks. Equipped with extra tanks the 12E has a maximum range of 676km. Production of both the 12E and 12E-4 is ran at about five a month.
A number were fitted with an Allison 250-C20 turbine as Soloy UH12E-SCL conversions. The 400shp Allison (derated to 305 shp) is mounted slanting backwards from the adaptor gearbox, leaving a large uncluttered area where the previous engine was.
UH-12E / OH-23G Engine: 305hp Textron Lycoming VO-540-A1A / Lycoming VO-540-C2A, 305 hp. TBO: 1200 hrs. Main rotor: 10.8 m / 35.3 ft. Seats: 3. Length: 40.7 ft. Height: 10.1 ft. Max ramp weight: 3100 lbs. Max takeoff weight: 3100 lb / 1410 kg. Standard empty weight: 1759 lbs. Max useful load: 610 kg / 1341 lbs. Max landing weight: 3100 lbs. Max sling load: 1000 lbs. Disc loading: 3.2 lbs/sq.ft. Power loading: 10.2 lbs/hp. Max usable fuel: 516 lbs. Max rate of climb: 993 fpm. Service ceiling: 15,000 ft. Hover in ground effect: 10,400 ft. Hover out of ground effect: 6800 ft. Max speed: 83 kts. Normal cruise @ 3000 ft: 51 kts. Max cruise: 80 kts Fuel flow @ normal cruise: 125 pph. Endurance @ normal cruise: 3.9 hr. Max range: 390 km. Seats: 3.
UH-12EL Engine: 305hp Textron Lycoming VO-540-A1A TOGW: 1400 kg
UH-12E-L3 Engine: Lycoming VO-540-C2B, 305 hp Main rotor diameter: 35 ft 5 in / 10.80 m Empty weight: 1759 lb / 798 kg Normal TO weight: 2800 lb / 1270 kg Max overload weight: 3100 lb / 1405 kg Max cruise SL: 78 kt / 90 mph / 145 kph Max ROC SL: 1290 fpm / 393 m/min Service ceiling: 15,200 ft / 4630 m Range w/aux fuel, 2800lb/1270kg: 379 nm / 437 mi / 703 km Seats: 3 Baggage capacity: 125 lb / 57 kg Cabin length: 5 ft 0 in / 1.52 m Cabin width: 4 ft 11 in / 1.50 m Cabin height: 4 ft 5 in / 1.35 m
Stanley Hiller Jr designed the two-seat Model 360 which first flew in 1948. It was derived from the UH-5 which had proved very unstable during trials and had subsequently been fitted with a new stability system patented as the Hiller ‘Rotormatic’. It entailed fitting the two-blade rotor with two small paddles which acted as a control rotor and were also connected to a hanging stick. This servo ‘paddle control’ system tilts the rotor head and actuates the cyclic pitch control.
Of all-metal construction with fixed tricycle undercarriage. Equipped with a fully enclosed cabin and rear fuselage, an overhead mounted control stick is attached to a Hiller rotor control. Power is by one 175hp Franklin 6V4-178-B32 engine. The prototype was registered N68940.
It received its FAA (Federal Aviation Administration) approval in October 1948 and a year later a production model designated Model 12 made the first transcontinental helicopter flight across the USA in the summer of 1949. At that time it still had an open cockpit, and the 178hp Franklin 6V4-178-B33 was in an open engine bay.
Hiller 360
In 1949 a Hiller 360 demonstrated a pilot-less cross-country flight with two observers well away from the pilot’s seat. The 25 mile flight over San Francisco Bay was at 3800 ft after a normal piloted take off.
Pilotless Hiller 360
Hiller 360 Engine: Franklin 6V4-200-C33, 200 h.p. Rotor diameter: 35 ft. Rotors: 2-blade main; 2-blade tail Fuselage length: 27 ft. 6 in. Loaded weight: 2,500 lb. Max. speed: 84 m.p.h. Ceiling: 9,400 ft. Typical range: 135 miles at 70 mph Seats: 3.
HTE-1 Engine: Franklin 178 hp Undercarriage: 3-wheel
All Aero 