RU2688649C2 - Aircraft short takeoff method - Google Patents

Abstract

FIELD: aviation.SUBSTANCE: invention relates to aerodrome equipment. Proposed method comprises starting device filling, aircraft and starting device mechanical connection. Horizontal component of mechanical loads is transmitted from launching device to aircraft so that total transmitted force coincides with aircraft motion vector. Vertical component of mechanical loads from aircraft to runway through launching device is transmitted to a lesser extent. Providing for movement of bundle aircraft - launching device by conversion of chemical energy stored in fuel, using aircraft propulsion device and accelerating jet propulsion unit of starting device in kinetic energy of translational movement to kinetic energy of value, which allows aircraft to take off due to traction of own propulsion plant. Aircraft and starting device mechanical disconnection is performed. Braking of starting device is ensured by reverse thrust of accelerating jet propulsion unit.EFFECT: invention is aimed at improvement of energy-mass efficiency of take-off.1 cl

Description

The method relates to aircraft technology, and in particular to methods of shortened take-off of aircraft. In the course of the development of aviation technology, various methods have emerged that make it possible to ensure the take-off of an aircraft with an insufficient length of the runway. Some of them are based on the use of a launching device - a trolley - to ensure the take-off of the aircraft. In this case, for further reference, it seems appropriate to introduce the term "bundle" aircraft - launching device "or abbreviated -" bundle of LASU ". To ensure the take-off of a bunch of LASU of a certain mass, it is required to expend a certain amount of kinetic energy. The ratio of the energy of the LASU bundle to its mass is an indicator of the energy-mass efficiency of the take-off.

There is a known method of taking off aircraft from merchant ships CAM ship (Catapult Aircraft Merchant Ship) (the site “Aviation, understandable to everyone.”, Article “Aircraft rocket boosters. Part 2.”, link to source (URL): http: // avia-simply .ru / aviacionnie-raketnie-uskoriteli-chast-2 /), according to which the mobile part of the launching device, which is a mobile starting ramp, is installed on the fixed part of the starting device, which is a special guide, the aircraft is installed on the mobile starting ramp, start engines aircraft and poro A hovered rocket booster mounted on a mobile starting ramp accelerates the launch ramp and the aircraft mounted on it by creating thrust engines of the starting ramp and aircraft, and mechanically separates the starting ramp and the aircraft.

This method has a number of significant drawbacks: first, the guides of the launcher have a significant passive mass and dimensions; secondly, due to the installation of a sufficiently heavy aircraft on the movable part of the launching device, which is a movable launch ramp, the latter also has a mass comparable with it and significant dimensions, which is necessary to ensure the required rigidity and strength of the structure. In addition, the launch facility becomes an additional load carried by the vessel both during launch and before and after launch. Moving in space of the moving and stationary parts of the launch device, both during launch and before and after launch, requires additional energy costs directly related to the mass of the launch facility. All of the above leads to a decrease in the energy-mass efficiency of ensuring take-off.

There is a method of launching an aircraft using a launch carriage with a propulsion system on liquid fuel (patent RU 2046071), which includes acceleration of the launch car to the take-off speed of the aircraft, braking of the launch car by reversing the thrust, characterized in that during braking the fuel is fed into the propulsion system starting carts from the tanks of the propulsion system of the aircraft.

This method has a number of significant drawbacks: due to the installation of a sufficiently heavy aircraft on the launch car, the latter has a mass comparable with it and significant dimensions, which is necessary to ensure the required rigidity and strength of the structure. In addition, the aircraft is forced during acceleration to carry a passive mass of fuel, which is used to brake the starting carriage by reverse thrust. All of the above leads to a decrease in the energy-mass efficiency of ensuring take-off.

Closest to the claimed method is a method of take-off of an aircraft using a launching device (according to the patent “Take off trolleys for flight vehicles)) -“ Launchers providing take-off of aircraft)), GB 2211155), including refueling of accelerating and shunting propulsion systems of the starting device, placement of the aircraft on the launching device, installation of the wheels of parallel wheel elements of the launching device in parallel, refueling of the aircraft, orientation of the bunch LASU on the take-off axis, acceleration of the aircraft by the joint work of the jet propulsion system of the aircraft and the accelerating propulsion system of the launching device until the aircraft reaches the detachment speed from the runway, resetting the speed of the launching device by cutting off the thrust of the accelerating propulsion system of the launching device, the subsequent possible moving the starting device to the desired position using shunting propulsion starts th device.

This method has a significant drawback: due to the installation of a sufficiently heavy aircraft on the launching device, the latter has a mass comparable to it and significant dimensions, which is necessary to ensure the required rigidity and strength of the structure. All of the above leads to a decrease in the energy-mass efficiency of ensuring take-off.

The aim of the claimed invention is to increase the energy-mass efficiency of ensuring take-off.

This goal is achieved by the fact that they carry out refueling of the launching device in the amount necessary to launch this type of aircraft of given weight in given weather conditions at a given length of the runway, produce a mechanical connection of the aircraft and the launching device. The horizontal component of the mechanical loads is transmitted from the launching device of the aircraft in such a way that the total transmitted force coincides with the motion vector of the aircraft, and the vertical component of the mechanical loads from the aircraft is transmitted to a lesser extent. Carry out the installation of ligaments of the aircraft - the launch device with the required vector of movement of the aircraft. Provide the movement of the ligaments of the aircraft - the launching device by converting chemical energy stored in the fuel, using the propulsion system of the aircraft and accelerating jet propulsion system of the launching device into the kinetic energy of the translational movement of the ligament aircraft - the starting device until the kinetic energy reaches the value allowing the aircraft due to the available thrust of its own propulsion system, take off without going beyond the limits of g this runway. Mechanical separation of the aircraft and the launching device is carried out. The braking of the starting device is provided by reversing the thrust of the accelerating jet propulsion system.

The subsequent movement of the launching device towards the initial position is ensured by reversing the thrust of the accelerating jet propulsion system of the starting device.

Thus, the stated goal has been achieved, namely: the energy-mass efficiency of ensuring take-off has been increased.

The proposed method consists in the fact that they first refuel the launching device, and the amount of refueling is chosen depending on the type of aircraft of a given weight in the given weather conditions for a given length of the runway. Then, the launch vehicle and fuselage of the aircraft are mechanically connected in such a way that during take-off, the starting device can be pushed by the aircraft with the required motion vector of the aircraft: for this, the horizontal component of the mechanical loads is transmitted from the launch device to the aircraft so that the total transmitted force coincides with the motion vector of the aircraft, and the vertical component of the mechanical loads transferred from the aircraft to the runway through the standard means of the aircraft to transfer mechanical loads to the runway - the landing gear of the aircraft. Next, on the runway set a bunch of LASU with the required vector of movement of the aircraft. Provide the movement of the aircraft by converting the chemical energy stored in the fuel of the propulsion systems of the aircraft and the launching device into the kinetic energy of the translational movement of the LASU bundle. The movement of the ligament of the aircraft - the launching device provides up to the achievement of kinetic energy of a value that allows the aircraft due to the available thrust of its own propulsion system to take off without leaving the limits of this runway. Then disconnect the aircraft and the launch device. Reduce the amount of thrust of the accelerating jet propulsion system of the launching device to a value at which the probability of damage from the launching device of the aircraft is minimized, for example, as a result of the collision of the aircraft and the launching device or the impact of the gas flow starting device from the accelerating jet propulsion system to the aircraft . Braking and subsequent movement of the launching device towards the initial position is ensured by reversing the thrust of the accelerating jet propulsion system of the starting device, for example, by deflecting the flow of gases from the nozzle introduced into the flow of gases by the shield or bucket. Moving the launch device using the reverse towards the original position can be performed either along a straight path, returning the launch pad to the launch site, or along a curved path with the aim of locating the launch pad in a place other than the launch site, and thus freeing the take-off runway the next aircraft.

The application of this method allows to increase the energy-mass efficiency of providing take-off, since with the described version of the mechanical connection of the aircraft and the launching device, the launching device pushes the aircraft with the required movement vector of the aircraft, making the starting device less perceived by the vertical component of the mechanical loads from the aircraft — significant part of the vertical component of the mechanical loads directly from the aircraft to the runway through the standard means of the aircraft to transfer mechanical loads to the runway - the landing gear of the aircraft. Thus, reducing the mass-dimensional characteristics of the launching device with constant energy characteristics of the LASU bundle allows to achieve higher acceleration values during takeoff and deceleration, which increases the energy-mass efficiency of takeoff. The choice of refueling volume also allows you to increase the energy-mass efficiency of take-off, because when refueling the accelerating jet propulsion system of the launching device, such parameters as aircraft weight, weather conditions, length of the take-off strip are taken into account, and depending on the set of these parameters, fill the required amount of liquid or place the required the amount of solid fuel sticks In addition, the use of the same accelerating jet propulsion system of the launching device both for the take-off of the aircraft and for subsequent deceleration of the launching device due to the reverse thrust of the accelerating reactive propulsion system of the launching device and its movement towards its original position performing the operations described above instead of using several propulsion systems that perform these operations separately, which is also e allows you to achieve higher values of acceleration during takeoff and during braking and, as a result, to reduce the length of the section of the movement of the bunch LASU and the stopping distance of the launching device. All of the above improves the energy / mass efficiency of providing take-off.

It is important to note that the use of this method eliminates the use of an additional device for its implementation, such as a special loader. Since the launching device pushes the aircraft, and does not carry it on itself, loading the aircraft on the launching device is not required. It also reduces the time for preparatory work and allows the cyclic launches of aircraft using a set of similar starting devices.

Thus, the stated goal has been achieved, namely: the energy-mass efficiency of ensuring take-off has been increased.

Claims (2)

1. The method of shortened takeoff of the aircraft, including refueling the launching device, mechanical connection of the aircraft and the launching device, transfer of mechanical loads of the ligament of the aircraft — the launching device to the runway, from which the aircraft takes off, the ligament installation of the aircraft — the starting device with the required direction the movement vector of the aircraft, providing the movement of the ligament the aircraft — the launching device is transformed by chemical energy stored in fuel using the propulsion system of the aircraft and accelerating jet propulsion system of the launching device into the kinetic energy of the translational motion of the ligament of the aircraft — the launching device until the kinetic energy reaches a value that allows the aircraft to fly up due to the propulsion of its own propulsion system without departing from the limits of the given runway, mechanical separation of the aircraft and launch device the launching device braking, moving the launching device in the opposite direction, characterized in that refueling is carried out to the extent necessary to launch this type of aircraft of a given weight under given weather conditions for a given length of the runway, the horizontal component of the mechanical loads is transmitted from the launching device to the aircraft in such a way that the total transmitted force coincides with the motion vector of the aircraft, and the vertical component of the mechanical loads from the aircraft take off the runway through the launching device to a lesser extent; braking of the launching device is provided by reversing the thrust of the accelerating jet propulsion system. 2. The method of shortened take-off of the aircraft according to claim 1, characterized in that the subsequent movement of the launching device towards the initial position is ensured by reversing the thrust of the accelerating jet propulsion unit of the launching device.