RU143725U1 - Subsonic Passenger Airplane - Google Patents

Abstract

1. Subsonic passenger aircraft containing the fuselage, tail, low-lying mechanized swept wing, made with elongation, with an average aerodynamic chord, offset from the nose of the aircraft, with sweep along the quarter line of the chords and with supercritical supporting profiles located under the varying span of the console installation angles of twist, two turbojet engines, the engine nacelles of which by means of pylons are installed under the wing consoles, as well as the tail unit with elevators and directions and tricycle retractable landing gear, characterized in that the wing is made with an elongation of λ≥11.3, and the average aerodynamic chord of the wing is located at a distance of 0.39-0.41 the length of the fuselage from the nose of the aircraft. 2. A subsonic passenger aircraft according to claim 1, characterized in that the installation angles of rotation of the supercritical support wing profiles are made varying in the span of the console in the range from φ = 3.5 ° to φ = 0.8 °, the nacelles of turbojet engines are made with dimensions corresponding to the thrust each of them in the range from R = 0.14 to R = 0.19 of the maximum take-off weight of the aircraft with the same bypass ratio of these engines in the range from m = 8.0 to m = 13.0.3. Subsonic passenger aircraft according to claim 1, characterized in that the fuselage in the passenger compartment is oval-shaped. 4. A subsonic passenger aircraft according to claim 1, characterized in that the engine nacelles of turbojet engines are installed at distances: from the front plane of the engine nacelle along its axis to the front edge of the wing in the plane of symmetry of the engine nacelle in the range from γ = 1.1 to γ = 1.2 average aerodynamic chords of the wing and from

Description

The technical field to which the utility model relates.

The utility model relates to the field of aviation, and more specifically to subsonic passenger aircraft.

State of the art

Many types of passenger aircraft are known in the art. Known aircraft containing the fuselage, wing, control and stabilizing surfaces, two engines mounted on the corresponding consoles of the wing, having a concave profile of the lower surfaces (see Mikeladze V.G., Titov V.M. "Basic geometric and aerodynamic characteristics of aircraft and missiles ". Handbook. - M .: mechanical engineering, 1982).

From the publication of patent RU 2277058 C2, publ. 03/10/2003, the main aircraft of variable passenger capacity is known, which consists of the fuselage, swept wing, vertical and horizontal tail, rudders and altitude, controls, aircraft systems and equipment. The wing is formed by the center section and the transition compartments, forming the total wing area as a direct function of the payload, and the ratio of the size of the transition compartment and the detachable part of the wing is selected from the condition that the ratio of the coordinates of the center of pressure and the average aerodynamic chord is approximately constant.

The closest analogue of the claimed utility model is a short-medium-range aircraft, see RF patent No. 2384463, publ. 03/20/2010. The near-medium-haul aircraft contains a low-lying mechanized wing, the average aerodynamic chord of which is located at a distance of 0.41-042 the length of the fuselage from the nose of the aircraft, with elongation λ≥11.5, sweep along the quarter line of the chords χ≥26.5 ° and with supercritical profiles located under the variable twist angles of the console, two turbojet engines, the engine nacelles of which are mounted under the wing consoles using pylons, as well as the tail unit with elevators and rudders hopornoe landing gear. The combination of structural elements of the specified aircraft, as well as the location of the average aerodynamic chord of the wing is not optimal, as a result of which the achievement of the best flight performance of the aircraft is not ensured.

Utility Model Essence

The problem solved by the claimed utility model is to reduce operating costs.

The technical result of the claimed utility model is to reduce costs, including fuel, during operation of the aircraft by improving flight performance by reducing balancing losses.

The specified technical result is achieved by the proposed subsonic passenger aircraft containing the fuselage, tail, low-lying mechanized swept wing, made with elongation, with an average aerodynamic chord, offset from the nose of the aircraft, with sweep along the quarter of the chords and with supercritical support profiles located under the changing according to the scope of the console with the installation angles of twist, two turbojet engines, the engine nacelles of which are installed under p with wing salts, as well as tail unit with elevators and rudders and a three-leg retractable landing gear, the wing of the proposed subsonic passenger aircraft is made with lengthening λ≥11.3, and the average aerodynamic chord of the wing is located at a distance of 0.39-0.41 of the fuselage length from nose of the plane.

In one embodiment of the proposed subsonic passenger aircraft, the installation angles of rotation of the supercritical support wing profiles are made varying in the span of the console in the range from φ = 3.5 ° to φ = 0.8 °, the nacelles of turbojet engines are made with dimensions corresponding to the thrust of each them in the range from R = 0.14 to R = 0.19 of the maximum take-off weight of the aircraft with the same degree of bypass of these engines in the range from m = 8.0 to m = 13.0,

In another embodiment of the proposed utility model, the fuselage in the passenger compartment is oval-shaped.

In the particular case of the implementation of the proposed utility model, the nacelles of turbojet engines are installed at distances: from the front plane of the nacelle along its axis to the front edge of the wing in the plane of symmetry of the nacelle - in the range from γ = 1.1 to γ = 1.2 of the average aerodynamic wing chord and from the axis of the nacelle to the wing chord in the plane of installation of the nacelle - in the range from ε = 0.25 to ε = 0.45 of the average aerodynamic chord of the wing.

In another particular case of the proposed utility model, the left and right turbojet engines and their engine nacelles are located relative to the plane of symmetry of the aircraft at a positive angle in the range from µ = 1.4 ° to µ = 1.6 ° to the axis of the turbojet, and in the vertical plane of symmetry the engine nacelle of the left and right turbojet engine is located at a positive angle in the range from θ = 1.8 ° to θ = 2.2 °.

In another embodiment of the proposed utility model, the wing sweep along the quarter-chord line is made in the range from χ = 25 ° to χ = 30 °.

In another embodiment, the proposed utility model of the wing is made with a narrowing in the range from η = 3.0 to η = 4.0.

Also, in yet another embodiment of the proposed utility model, the average aerodynamic chord of the wing is from b _a = 0.09 to ba = 0.10 of its span.

In another embodiment of the proposed utility model, each wing console is mounted at an angle of transverse V in the range from ψ = 4.5 ° to ψ = 5.5 °.

In another embodiment of the proposed utility model, each wing console is made with a rectilinear - root and swept trailing edge, mated along a curve described by a third-order spline.

Also, in another particular case of the implementation of the proposed utility model, the oval-shaped outer surface of the fuselage in the passenger compartment is made with a height to width ratio in the range from ∑ = 0.90 to ∑ = 0.98.

In another embodiment of the proposed utility model, the fuselage is made with a section of the passenger compartment with seats, while the width of the passage on the section of the passenger compartment of the fuselage between the seats is configured to provide a passage for the passenger when the stewardess or steward with the trolley is in the passage and at least is at least at least 1.3 the width of the backrest of a passenger seat.

Brief Description of the Drawings

Details, features, and also advantages of the present utility model follow from the description of examples of the implementation of the claimed utility model using the drawings, which show:

FIG. 1 - general view of the aircraft, side view;

FIG. 2 - general view of the aircraft, top view;

FIG. 3 - general view of the aircraft, front view;

FIG. 4 - section AA.

In the figures, the positions indicate the following structural elements of the proposed subsonic passenger aircraft:

fuselage (1); wing (2); right wing console (3); left wing console (4); the root trailing edge of the wing consoles (5); swept trailing edge of wing consoles (6); curve (7); aileron (8); sectional slats (9); air brake (10); interceptor (11); flaps (12); section of the passenger compartment (13); engine nacelle (14); pylon (15); horizontal tail (16); vertical tail (17); elevator (18); rudder (19); front chassis (20); main chassis (21).

Utility Model Disclosure

The claimed passenger aircraft provides for a capacity of from 150 to 180 passengers and a flight range in the range from H = 3500 to H = 5000 km.

The aircraft contains a low-lying relative to the fuselage (1) mechanized swept wing (2).

Wing (2) is made with lengthening λ≥11.3, with sweep along the quarter-chord line in the range from χ = 25 ° to χ = 30 °, with a narrowing in the range from η = 3.0 to η = 4.0, with the average aerodynamic chord in the range from b _a = 0.09 to b _a = 0.10 of the wingspan 2. The average aerodynamic chord of the wing is located at a distance of 0.39-0.41 the length of the fuselage from the nose of the aircraft.

The wing (2) is formed by supercritical support profiles (not shown in Fig.), Which are located at the installation angles of the slip twist, varying in the span of the console (3) or (4) in the range from φ = 3.5 ° to φ = 0.8 °.

The right (3) and left (4) wing consoles (2) are installed at an angle of transverse V in the range from ψ = 4.5 ° to ψ = 5.5 °.

The rectilinear root (5) trailing edge and swept (6) trailing edge of the right (3) and left (4) wing consoles (2) are conjugated along curve (7), described by a third-order spline.

Mechanization of the right (3) and left wing consoles (4) of the wing (2) includes aileron (8), sectioned slats (9), air brake (10), spoilers (11) and flaps (12).

The outer surface of the fuselage (1) in the section (13) of the passenger compartment is oval-shaped with a height to width ratio in the range from ∑ = 0.90 to ∑ = 0.98.

The width of the aisle in the section (13) of the passenger compartment of the fuselage (1) between the seats is made with the possibility of the passage of a medium-sized passenger while the stewardess with a trolley is in the aisle (Fig. 4).

The aircraft contains two turbojet engines (not shown in FIG.) With the same bypass ratio in the range from m = 8.0 to m = 13.0 and with a thrust of each of them in the range from R = 0.14 to R = 0.19 maximum take-off weight of the aircraft.

The engine nacelles (14) of the turbojet engines are made with dimensions corresponding to the bypass ratio and the thrust of the turbojet engines, and by means of pylons (15) are installed under the right (3) and left (4) wing consoles (2) at the following distances:

- from the axis of the engine nacelle (14) to the plane of symmetry of the aircraft - in the range from ρ = 0.30 to ρ = 0.35 wing span (2),

- from the front plane of the engine nacelle (14) along its axis to the front edge of the right (3) and left (4) wing consoles (2) in the installation plane of the engine nacelle (14) - in the range from γ = 1.1 to γ = 1.2 wing aerodynamic chord (2),

- from the axis of the nacelle (14) to the chord of the right (3) and left (4) wing consoles (2) in the plane of installation of the nacelle (14) - in the range from ε = 0.25 to ε = 0.45 of the average aerodynamic wing chord ( 2) the portion (13) of the fuselage (1).

In the direction of flight, the axis of the right turbojet engine and its nacelle (14) is located relative to the plane of symmetry of the aircraft at a positive angle in the range from μ = 1.4 ° to μ = 1.6 °, the axis of the left turbojet engine and its nacelle (14) is relative to the plane of symmetry of the aircraft at a negative angle in the range from μ = 1.4 ° to μ = 1.6 °, and in the vertical plane of symmetry, both nacelles are located at a positive angle in the range from θ = 1.8 ° to θ = 2.2 °.

The proposed subsonic passenger aircraft contains horizontal (16) and vertical (17) tail units with elevators (18) and directions (19) and a three-leg landing gear retractable for the duration of the flight: front (20) and main (21).

During the flight of the aircraft in cruising mode, the right (3) and left (4) wing consoles (2) are deformed under the influence of the incoming air flow. The twist angles of the supercritical support profiles from the position of the installation angles of the slip twist along the span of the console in the range from φ = 3.5 ° to φ = 0.8 ° change to the flight twist position shown in FIG. 5.

The profiling of the wing (2) allows the safe implementation of the maximum balanced quality with the aerodynamic lift coefficient C _y ~ 0.6 when flying at a speed of M ~ 0.8 (see Fig. 7). To minimize balancing losses, it is necessary to carry out a cruise flight with the centers of mass of the aircraft shifted as far back as possible. This is achieved by shifting the wing and, accordingly, the average aerodynamic chord of the wing forward. Due to this, it is possible to raise the initial altitude of the cruise flight from ~ 10700 m to ~ 11300 m at a flight speed corresponding to the maximum flight range.

High aerodynamic quality during cruising flight with a speed in the range from 0.78 to 0.82 of the speed of sound is achieved by a combination of deformation of the wing and the implementation of the rear alignments in cruising flight (see Fig. 6) with the following parameters:

- the thrust of each of the turbojet engines is from R = 0.14 to R = 0.19 of the maximum take-off weight of the aircraft with the same bypass ratio of these engines in the range from m = 8.0 to m = 13.0;

- the sizes of the engine nacelles (14) correspond to the thrust and the degree of dual-circuit engines;

- the low wing (2) has an elongation of λ≥11.3 and a sweep along the quarter line of the chords from χ = 25 ° to χ = 30 °.

The parameter MK _max is an indicator of the aerodynamic perfection of a passenger aircraft. One of the main requirements of the passenger transportation market for promising airliners is to increase the cruising speed of flight at maximum range. An increase in the MK _max parameter allows one to reduce take-off thrust with a fixed thrust-weight ratio characteristic of this class of passenger aircraft, which, in turn, can reduce fuel consumption in all flight modes.

Minimizing the curb weight and take-off weight of the aircraft with the same transport work ensures a decrease in direct operating costs by ~ 3%.

The increase in fuel efficiency of the aircraft provides a decrease in direct operating costs by ~ 4%.

Due to the provision of regular and safe cruising flights due to С _у ~ 0.6 at М ~ 0.8 in the altitude range from H = 11000 m to H = 12500 m, previously used mainly by administrative aircraft, the workload on air traffic controllers is reduced and efficiency is increased air traffic control.

Due to the fact that the engine nacelles (14) are installed at distances:

- from the front plane along the axis of the engine nacelle (14) to the front edge of the right (3) and (4) left wing consoles (2) in the plane of symmetry of the engine nacelle (14) - in the range from γ = 1.1 to γ = 1.2 average aerodynamic wing chords (2),

- from the axis of the nacelle (14) to the chord of the right (3) and left (4) wing consoles (2) in the plane of symmetry of the nacelle (14) - in the range from ε = 0.25 to ε = 0.45 of the average aerodynamic wing chord ( 2), the flight characteristics of the aircraft are significantly improved.

The optimal mutual spatial arrangement of the fuselage (1), wing (2) and engine nacelles (14) minimizes interference losses, which contributes to an increase in the maximum aerodynamic quality of the order of ~ 1%.

Due to the fact that the outer surface of the fuselage (1) in the passenger compartment section (13) is oval-shaped with a height to width ratio in the range from 0 = 0.90 to ∑ = 0.98, the parameters of the cargo compartment of the aircraft are significantly improved. In addition, the time required for loading and unloading the cargo compartment is reduced, and, accordingly, the required turnaround time of the aircraft at the airport is reduced.

The width of the passage on the section (13) of the passenger compartment of the fuselage (1) between the seats is 1.3 times the width of the back of the seat. Due to the fact that the width of the aisle in the section (13) of the passenger compartment of the fuselage (1) between the seats is made with the possibility of the passage of a medium-sized passenger while the stewardess or steward is in the aisle with a standard trolley, when operating the aircraft on the ground, the flight comfort of the aircraft significantly increases. Due to the greater speed of boarding and disembarking passengers, the required turnaround time of the aircraft at the airport is accordingly reduced.

Due to the reduction in aircraft maintenance time for re-departure, it provides an increase in the annual flight time of each aircraft by ~ 1%.

Claims (12)

1. Subsonic passenger aircraft containing the fuselage, tail, low-lying mechanized swept wing, made with elongation, with an average aerodynamic chord, offset from the nose of the aircraft, with sweep along the quarter line of the chords and with supercritical supporting profiles located under the varying span of the console installation angles of twist, two turbojet engines, the engine nacelles of which by means of pylons are installed under the wing consoles, as well as the tail unit with elevators and directions and tricycle retractable landing gear, characterized in that the wing is made with an elongation of λ≥11.3, and the average aerodynamic chord of the wing is located at a distance of 0.39-0.41 the length of the fuselage from the nose of the aircraft. 2. A subsonic passenger aircraft according to claim 1, characterized in that the installation angles of twist of the supercritical reference wing profiles are made varying in the span of the console in the range from φ = 3.5 ° to φ = 0.8 °, the nacelles of turbojet engines are made with dimensions corresponding to the thrust of each of them in the range from R = 0.14 to R = 0.19 of the maximum take-off weight of the aircraft with the same degree of bypass of these engines in the range from m = 8.0 to m = 13.0. 3. Subsonic passenger aircraft according to claim 1, characterized in that the fuselage in the passenger compartment is oval-shaped. 4. A subsonic passenger aircraft according to claim 1, characterized in that the engine nacelles of turbojet engines are installed at distances: from the front plane of the engine nacelle along its axis to the front edge of the wing in the plane of symmetry of the engine nacelle in the range from γ = 1.1 to γ = 1, 2 of the average aerodynamic chord of the wing and from the axis of the nacelle to the chord of the wing in the plane of installation of the nacelle - in the range from ε = 0.25 to ε = 0.45 of the average aerodynamic chord of the wing. 5. A subsonic passenger aircraft according to claim 1, characterized in that the left and right turbojet engines and their engine nacelles are located relative to the plane of symmetry of the aircraft at a positive angle in the range from μ = 1.4 ° to μ = 1.6 ° to the axis of the turbojet engine and in the vertical plane of symmetry the nacelle of the left and right turbojet engine is located at a positive angle in the range from θ = 1.8 ° to θ = 2.2 °. 6. The subsonic passenger aircraft according to claim 1, characterized in that the wing sweep along the quarter line of the chords is made in the range from χ = 25 ° to χ = 30 °. 7. The subsonic passenger aircraft according to claim 1, characterized in that the wing is made narrowing in the range from ŋ = 3.0 to ŋ = 4.0. 8. The subsonic passenger aircraft according to claim 1, characterized in that the average aerodynamic chord of the wing is from b _a = 0.09 to b _a = 0.10 of its wingspan. 9. Subsonic passenger aircraft according to claim 1, characterized in that each wing console is installed at an angle of transverse V in the range from ψ = 4.5 ° to ψ = 5.5 °. 10. Subsonic passenger aircraft according to claim 1, characterized in that each wing console is made with a straight-line - root and swept trailing edges, mated along a curve described by a third-order spline. 11. The subsonic passenger aircraft according to claim 1, characterized in that the oval-shaped outer surface of the fuselage in the passenger compartment section is made with a height to width ratio in the range from Σ = 0.90 to Σ = 0.98. 12. A subsonic passenger aircraft according to claim 1, characterized in that the fuselage is made with a section of the passenger compartment with seats, while the width of the passage in the section of the passenger compartment of the fuselage between the seats is arranged to allow passage of the passenger while the stewardess or steward is in the aisle with a trolley at least at least 1.3 times the width of the back of the passenger seat.