RU2325307C1 - Method of aircraft take-off - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: in a process of aircraft propulsion along a take-off runway the true speed of an aircraft movement is being constantly measured and correspondingly the consumption of air through air inlet of an engine is being changed by means of adjusting frequency of a low pressure rotor rotation to values when at a given speed a vortex flow between an air inlet and air field surface does not occur. Adjusting of a rotation frequency of the rotor of a low pressure compressor is stopped at a threshold value of a true speed of an aircraft, when a vortex flow is blown off, and an engine is set to maximum modes of operation. In case of engines with a thrust vector control a gas jet of a jet nozzle additionally in the beginning of steering is inclined upward at an angle providing unloading of a front pole of undercarriage while maintaining controllability of an aircraft.

EFFECT: purpose of the invention is to eliminate ingress of particles of airfield trash into an engine air inlet during aircraft takeoff.

2 cl

Description

The invention relates to the field of aviation, in particular to methods of aircraft take-off, providing protection for the main engines of the aircraft from foreign objects from the taxiway and the runway through the air intake during taxiing and take-off runway.

One of the main reasons for foreign objects getting into the air intake during taxiing and take-off when taking off the aircraft is throwing them with a vortex cord arising between the surface of the airfield and the air intake.

There is a known method of take-off with an “thrust” of engine thrust, in which the plane is pulled off and its acceleration is started at constant reduced engine operating conditions, which makes it unlikely that an intense vortex cord will be able to throw solid particles into the intake area (Materials of the 6th International Scientific technical symposium “Aviation technologies of the XXI century: new frontiers in aviation science”, report by Zaitseva GA, Larionova NS “Methods of calculation and experimental determination of kinematic Characteristics of the aircraft during takeoff motion "with dodachey" traction motors and the probability of entering of foreign objects into powerplant g. 2001 "). A subsequent increase in the engine operating mode is made after reaching the speed of the incoming air flow such a value at which the occurrence of a vortex cord at maximum air flow is impossible.

There are no systems on modern airplanes informing the pilot about the values of the mass air flow rate (G _in ) through the air intake; therefore, during acceleration, the pilot cannot take off at the optimal values (G _in ). Acceleration is carried out at constant minimum values (G _in ), which significantly increases the take-off run.

A known method of aircraft takeoff using a controlled thrust vector is that before the take-off when the plane is on the brakes, create more thrust, while at the beginning of the take-off, the controlled nozzles are deflected up to raise the nose wheel (Russian Patent No. 2128127, MKI6 V64C 15/02). This method allows to reduce the takeoff run of the aircraft from 35 to 45%.

The disadvantage of this take-off method is that the aircraft, which is on the brakes, at high engine operating conditions has a large air mass flow through the air intake, which can cause the formation of a vortex cord, which intensively collects airdrome objects under the air intake of the aircraft. In addition, a raised nose wheel in the initial take-off phase affects the controllability of the aircraft during take-off.

The problem to which the claimed invention is directed, is to prevent particles of airfield clogging from entering the air intake from the taxiway and the runway during taxiing and take-off.

The technical result is achieved by the fact that in the method of taking off the aircraft, which consists in taxiing the aircraft to the runway and increasing the thrust of its engine during the take-off run, continuously in the process of taxiing and take-off the aircraft measures its true speed and, accordingly, its value changes the air flow through the engine’s air intake by adjusting the rotational speed of the low-pressure rotor to the experimentally determined during testing the limit of permissible values at which no cord between the air intake and the surface of the airfield, and the regulation of the rotational speed of the low pressure rotor depending on the true speed values continues until the engine reaches its maximum operating conditions.

In addition, for airplanes with engines with a directional thrust vector, at the beginning of taxiing, the gas stream emanating from the jet nozzle of the engine is deflected upward by an angle not exceeding the maximum permissible angle predefined during testing, which ensures the maximum possible unloading of the front landing gear while maintaining controllability the plane.

Regulation of the rotational speed of the low-pressure rotor of the engine depending on the values of the true speed of the aircraft, continuously measured during taxiing and take-off, allows maintaining such an air flow through the air intake of the engine that does not lead to vortex formation, and, consequently, throwing particles of airfield clogging to the engine inlet .

The direction of the gas jet emanating from the jet nozzle of the engine (for airplanes having engines with a directional thrust vector) is upward by an angle that does not exceed the maximum permissible angle predefined during testing, which ensures the maximum possible unloading of the landing gear while maintaining aircraft controllability, allows maintaining the stable movement of the aircraft along the airfield, increase the distance between the air intake and the surface of the airfield, which reduces the speed of respect the whirlwind of the plane.

It is possible to assess the degree of protection of the engine from the ingress of aerodrome clogging particles by comparing the engine protection parameter K _in (t _p ) with its boundary value during acceleration, less than which vortex cords are practically absent or do not have sufficient intensity

where G _in - mass air flow through the air intake during taxiing and acceleration of the aircraft, kg / s;

G _in / 20,1 - air volumetric flow rate during takeoff, m ³ / s;

t _p - time of movement along the taxiway and acceleration of the aircraft on the runway during takeoff, sec;

H - the height of the central point of the inlet section of the air intake above the surface of the airfield, m;

And _in - correction factor, taking into account the influence of the layout of the air intake on the plane.

As a result of special studies, it was found that, with the value of the engine protection parameter from vortex cords K _{in, gr} ≤1 m / s, vortex cords are practically absent in a wide range in wind speed and direction. The higher the value of the security parameter K _in (t _p ) from its boundary value, the more intense the vortex cord and the higher the likelihood of damage to the engine by foreign objects raised from the surface of the airfield.

The speed of the incoming air flow during the movement of the aircraft, at which there is a guaranteed separation of the vortex cord from the surface of the airfield, is called the speed of blowing of the vortex and is determined by the following empirical formula, m / s:

The value of V _sd (t _p ) depends on the layout of the air intake, as well as on the value of G _in (t _p ). When the true speed of the aircraft exceeds V _ist (t _p ) the vortex blowing speed V _ist (t _p )> V _sd (t _p ), vortex cords are shorted to the airfield surface.

It is possible to minimize the likelihood of airborne debris particles getting into the air intake during taxiing and take-off by adjusting G _in (t _rad ) depending on the true speed value, the possibility of high-precision measurement of which has appeared at present. As a controlled parameter characterizing the engine operating mode, the reduced rotational speed of the low pressure rotor is used taking into account the outdoor temperature, ambient pressure and take-off weight of the aircraft.

The proposed method of takeoff is as follows.

Before the operation of the aircraft, the limits of the air flow rate G _in = f (V _East ), at which at the given speed the formation of a vortex cord between the air intake and the surface of the airfield, does not occur, are calculated and refined experimentally for each value of the true speed of the aircraft. All data is embedded in the on-board automation. During taxiing and take-off, the true speed of the aircraft is continuously measured and, accordingly, the rotational speed of the low-pressure rotor is automatically controlled according to each measured value, at which the thrust and the corresponding mass air flow determine the value of _Kin and equality (1). The on-board automation of a modern engine has the ability to accurately control the process of changing the fuel consumption of the main engine circuit (by changing the rotational speed of the low pressure rotor) depending on the value of the true speed of the aircraft.

Thus, the movement in the process of taxiing and taking off is carried out at the engine operating modes with optimal air flow through the air intake, in which the occurrence of an intense vortex cord is unlikely.

On airplanes with engines with a controlled thrust vector (you can change the direction of the thrust vector, for example, by turning the jet nozzle of the engine), it is possible to provide more effective protection of engines from particles of airfield clogging and to reduce the take-off length.

For this purpose, at the beginning of taxiing, by turning the jet nozzle, the gas jet emanating from it is deflected upward at such an angle as to ensure controllability of the aircraft and maximum unloading of the landing gear of the front landing gear, i.e. the front pillar wheel must not be torn off from the runway. As a result, the distance between the air intake and the surface of the aerodrome - H is increased, which will lead to a decrease in K _in (t _p ) and thereby further reduce the likelihood of a vortex line. In addition, the deviation of the gas stream up during taxiing will significantly reduce the impact on the surface of the track and on other nearby or taking off planes.

With access to the runway, the aircraft begins to move without braking with a gas jet deflected at the beginning of taxiing coming out of the jet nozzle, and the low-pressure rotor speed is also regulated depending on the true speed of the aircraft until the true speed reaches the speed of blowing the vortex, after which the engine automatically reaches maximum operating modes, and the angle of deviation of the gas stream decreases to a value that excludes aircraft the critical angle of attack. The return of the gas stream to its original position is carried out upon reaching a predetermined flight speed and a stable climb.

EFFECT: invention makes it possible to minimize the entry of airfield pollution into the engine air intake during take-off of the aircraft.

Claims (2)

1. The method of aircraft take-off, which consists in taxiing the aircraft to the runway and increasing the thrust of its engine during the take-off run, characterized in that its true speed is continuously measured during the taxiing and take-off run, and accordingly its value changes the air flow through the engine’s air intake by adjusting the frequency rotation of the low-pressure rotor to the limit of permissible values experimentally determined during testing, at which a vortex cord does not form at a given speed between duhozabornikom and airport surface, wherein the frequency control low-pressure rotor, depending from the actual speed values continue to exit the engine at the maximum its operating modes. 2. The method of take-off of an airplane according to claim 1, characterized in that for airplanes having engines with a thrust directionally directional vector, at the beginning of taxiing, the gas stream emanating from the jet nozzle of the engine is turned upward by an angle not exceeding the maximum defined during testing allowable angle, providing the maximum possible unloading of the front landing gear while maintaining the controllability of the aircraft.