RU2793976C1 - Twin-rotor helicopter with engine thrust vector control - Google Patents

Abstract

FIELD: aviation; designs of rotary-wing aircraft.

SUBSTANCE: helicopter with two main propellers contains a fuselage, a power unit with a gearbox, located in the lower part of the fuselage. The engine air intake passes around the bearing axis through the fuselage to its upper part with access to open space. The tips of the blades of the upper and lower propellers are mechanically connected in pairs. The blade turning rods of the upper and lower rotors are mechanically connected to a common swashplate. The reaction moment of the rotors is balanced by the controlled thrust vector of the engine using a rotary engine nozzle, mounted pivotally with the ability to rotate using control wiring to rotate the helicopter around a vertical axis.

EFFECT: reduced size of the helicopter, reduction of the centre of gravity of the helicopter, exclusion of flutter, overlapping of the rotor blades.

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Description

The invention relates to the field of aviation, in particular, to the designs of helicopters. There are a number of basic design schemes for jet moment compensation and helicopter control using both a single and several rotors. The reactive moments in schemes with two rotors are mutually compensated by synchronous multidirectional rotation of the two screws. There are coaxial, longitudinal and transverse layouts of rotors, and their combination. The common advantage of such schemes is the absence of power losses for reactive torque compensation. The coaxial rotor was known long before the idea of creating a helicopter with a tail rotor: for example, in 1754, the "father of Russian science" Mikhail Lomonosov proposed using a mechanism with coaxial screws to lift a meteorological probe, which was driven by a winding spring. • The first patent for the coaxial arrangement of the rotors of an aircraft was issued in 1859 to the Englishman Henry Bright. • In France, Poton de Amercourt in 1860 built a coaxial helicopter model with a steam engine. • Igor Sikorsky took his first steps in the helicopter industry in 1900 with prototypes of unmanned helicopters with a coaxial propeller. • In 1914, the Dane Jacob Ellehammer designed his coaxial helicopter. • In Austria, Stefan Petrozi built several coaxial unmanned helicopters with electric motors during 1917-1920. The helicopter could only be in hover mode. • Argentinean Raul Pescara built a coaxial helicopter in 1919-1920; the helicopter had 4 propellers, pairs of propellers connected like a biplane rotated in opposite directions. In the early 1920s, Raul Pescara worked on a coaxial helicopter, in which he first used a swashplate to control the helicopter. • In 1930, the Italian Corradino d'Ascanio built a coaxial helicopter controlled by servo blades, a similar solution used on the Kaman HH-43 Huskie. • During the years 1930-1936, the first coaxial helicopter with swashplates was built, it was built by the French Louis Breguet and René Doran. The first fully controlled helicopter was the Laboratory Gyroplane, built by Louis Charles Breguet and René Doran in 1936. • American Stanley Hiller in 1944 built the first coaxial helicopter XH44 with all-metal ultra-rigid steel blades.

• In the USSR, the Yakovlev helicopter first took to the air on December 20, 1947, and the Kamov Ka-8 helicopter on November 12, 1947. However, it was for the Kamov design bureau that the coaxial scheme became the main one; to this day, Kamov helicopters are the only mass-produced helicopters with a coaxial scheme in the world. Advantages of the coaxial scheme: • minimum overall dimensions, since the blades of coaxial propellers are shorter than the main blades of helicopters with a tail rotor of a similar class; • compact transmission. Almost the entire transmission is located along one shaft; • comparative ease of management. All controls are located next to the transmission, and when performing maneuvers, additional power from the engines is not expended; • better stability during straight motion at high speed due to vibration reduction; • a smaller number of critically vulnerable components, such as the tail boom and tail rotor of single-rotor helicopters; • greater thrust-to-weight ratio compared to the traditional scheme - at least 20% in hovering mode. No power loss to the tail rotor; • aerodynamic symmetry of the scheme. A coaxial device can fly in any direction with almost the same efficiency; • reduction of vibrations, which is facilitated by the smaller size of the rotors; • safety for service personnel. The absence of a tail rotor reduces the chance of injury. Disadvantages: The coaxial helicopter has large dimensions in height. The complex design of the gearbox with output shafts on two axles, two swashplates increase the cost of production, repair and maintenance. Counter-rotating rotor blades allow them to overlap, destroy and destroy the helicopter. Helicopters with the location of the power plant and gearbox at the top of the fuselage, due to the high location of the center of mass, roll over when landing on water. The purpose of the invention is to lower the center of mass of the helicopter, reduce the dimensions of the helicopter, simplify the design of the helicopter gearbox, compensate for the reactive moment of the rotors by the controlled thrust vector of the engine, eliminate flutter and overlap of the rotor blades, bleed the engine from the top of the fuselage to prevent foreign objects from entering the engine. Two main propellers (rotors) placed on a common vertical axis rotate in the same direction. The power plant with a gearbox is located in the lower part of the fuselage to lower the center of gravity of the helicopter, which prevents the helicopter from rolling over when landing on water.

The engine air intake passes around the bearing axis through the fuselage to its upper part with access to open space. This technical solution makes it possible to take air for the engine from the top of the fuselage, which eliminates the ingress of foreign objects into the engine and its dust pollution. Power from the helicopter's propulsion system to drive the rotors is transmitted through a gearbox with a single output shaft passing through the fuselage. To control the blades of both rotors, one common swashplate is used, which is mechanically connected to the blades of the upper rotor and to the blades of the lower rotor in pairs. The ends of the spars of the blades of the upper and lower rotors are mechanically connected in pairs. This technical solution eliminates flutter and overlap of rotor blades, the destruction of which leads to the death of the helicopter. The scheme of a helicopter with two rotors on a common axis, rotating in the same direction, allows you to increase the lifting force of the main propellers with a smaller diameter of the rotors, reduce the height of the helicopter by reducing the distance between the rotors. The use in the proposed design of a gearbox with an output shaft on one axis, one swashplate simplifies the design, reduces the cost of its production, repair and maintenance. The reaction moment of the rotors is balanced by the controlled thrust vector of the engine using a rotary engine nozzle, mounted pivotally with the ability to rotate using control wiring to rotate the helicopter around a vertical axis.

Claims (1)

A twin-rotor helicopter with a controlled engine thrust vector, consisting of a fuselage, a power plant with a gearbox located in the lower part of the fuselage, two rotors rotating in the same direction around a common axis, the tips of the rotor blades are mechanically connected in pairs: the upper with the lower, the thrust of the rotation of the blades of the upper and the lower rotors are mechanically connected to a common swashplate, characterized in that the engine air intake passes around the carrier axis through the fuselage to its upper part with access to the open space, the reactive moment of the rotors is balanced by the controlled engine thrust vector using a rotary engine nozzle mounted pivotally with the ability to rotate using control wiring to rotate the helicopter around a vertical axis.