KR20100072668A - A natural laminar flow airfoil for very light jets - Google Patents

Abstract

PURPOSE: A natural laminar airfoil for a small jet is provided to enable passengers to cost-efficiently use a plane by reducing fuel consumption. CONSTITUTION: A natural laminar airfoil(200) for a small jet comprises a top surface and a bottom surface. The top surface is curved. The bottom surface is formed in the bottom of the airfoil. A maximum thickness ratio of the airfoil is 14~16%. The airfoil reduces drag by delaying the succession of air current from laminar flow to turbulence flow.

Description

Natural Laminar Flow Airfoil for Very Light Jets

FIELD OF THE INVENTION The present invention relates to natural laminar flow airfoils for small jets, and more particularly to transition from laminar flow of turbulent flow to turbulence flow on the surface of the main blade. The present invention relates to a natural laminar flow airfoil for a small jet that can reduce drag by retarding.

As shown in FIG. 2, the airfoil 300 is generally a device such as an effective reaction from the air flowing through its surface, and is formed by the upper surface 240 and the lower surface 250. Tail wings and propellers may be an example of the airfoil (300).

The airfoil 300 has a different amount of lift depending on the demonstration line 230, which is a straight line connecting the leading edges of the leading edge 210 and the trailing edge 220. The amount of drag generated also varies.

Angle of attack refers to an angle between the demonstration line 230 and the direction of the relative airflow. The angle of attack is an aerodynamic angle that can support the aircraft and is a generating factor. This angle of attack can reach the out of the running car window, depending on the angle of the hand can feel the shape of the angle of attack. When the palm is level with the ground, there is little angle between the palm and the relative wind, so the resistance to the hand is minimal, but when the palm and the ground are at an angle, the hand is forced to move up or down. At this time, the angle between the palm and relative wind is the angle of attack.

Angle of Incidence refers to an angle between the front and rear axis of the body and the demonstration line 230. The front-rear axis refers to a straight line, ie, a longitudinal axis, running from front to rear of the fuselage. The mounting angle (approximately 1-3 degrees) is measured by the angle at which the main wing is mounted on the fuselage. The mounting angle is fixed so that the pilot cannot change this.

The mounting angle is determined at the time of designing the aircraft, which is equivalent to the angle of attack where the ratio of lift and drag is maximum. For example, if the mounting angle is 2 degrees, the main wing is normally mounted on the fuselage, that is, the main wing is mounted so that the angle between the demonstration line 230 of the airfoil 300 and the front and rear axes of the fuselage is 2 degrees. The mounting angle is fixed but the angle of attack can change the pilot, which is related to the direction of flight.

At zero angle of angle of attack, the pressure at the lower surface 250 of the main wing is equal to the atmospheric pressure, in which case all lift is caused by the pressure reduction (lower than atmospheric pressure) of the upper surface of the main wing 240.

In the state where the angle of attack is small, the impact of air or the pressure (higher than atmospheric pressure) hitting the lower wing 250 is almost negligible, so most of the lift is caused by the decrease in pressure of the upper wing 240.

And as the angle of attack increases, the impact or positive pressure of the air on the lower surface of the main wing 250 increases, but the effective curvature of the airfoil also increases as long as air flows along the curve of the main wing on the upper surface of the main wing 240. Since the air flow of the main wing upper surface 240 must flow a longer distance, the pressure is reduced.

This is because Bernoulli's definition requires a faster flow in order to flow longer distances, resulting in a greater pressure drop, for two reasons: an increase in the pressure at the bottom of the main wing 250 and a pressure drop at the top of the main wing 240. A large pressure difference occurs in the upper surface 240 and the lower surface 250 of the main blade. This large pressure difference generates upward force, or lift. At the same time, drag, the force to pull behind, also occurs.

However, when the angle of attack increases from about 18 degrees to 20 degrees, air cannot flow smoothly on most of the main wings 240. This is because an excessive change in the direction of flow is required. Airflow flows back immediately after leaving the upper surface 240 where the camber is maximized. This point is called a transition point. At the transition point, when air flows along the wing surface, vortex or bubbles, or turbulence, are generated. Turbulence at the wing surface leads to an increase in drag.

The transition point is moved toward the front edge 210 as the angle of attack increases, and the turbulence generation range deviated from the main wing upper surface 240 continues toward the front edge 210 so that the drag increases rapidly.

In the past, NASA64 series and NLF series airfoils have been developed and applied to aircrafts. Recently, Hondajet and Eclipse 500, which are small jets, have been adopted. However, the problems of drag increase due to the expansion of turbulence generation range are not improved. have.

The present invention has been made to solve the above problems, an object of the present invention is to delay the transition from the laminar flow of the air flow along the airfoil to the turbulent flow, that is, to move the transition point to the back of the wing, the drag is small The large drag bucket provides an eco-friendly and economical natural laminar airfoil for small jets with low fuel consumption during cruising and ascending flights.

The natural laminar flow airfoil for a small jet of the present invention is applied to the airfoil of the small jet, and includes an upper surface with a curved surface formed on the upper surface and a lower surface formed on the lower surface, wherein the airfoil flows from the upper surface and the lower surface. It is characterized by delaying the transition of c).

In addition, the airfoil is characterized in that the maximum thickness ratio is 14 to 16%, the point where the maximum thickness ratio is 50 to 60% from the front line on the protest line.

인 것을 특징으로 한다.In addition, the airfoil has a driving Reynolds number

It is characterized by that.

In addition, the profile of the upper surface and the lower surface is the upper coordinate value y_upper / c and lower coordinate value y_lower / defined in x / c when a distance from the front forward to the rear forward along the protest line is x / c . defining a c, and is characterized in that the upper surface formed by the coordinates (y_upper / c) and a lower surface coordinates (y_lower / c) corresponding to the table below, based on the x / c.

x / c y_upper / c x / c y_lower / c 0.000000 0.000000 0.000000 0.000000 0.000085 0.000873 0.000028 0.000160 0.000297 0.001902 0.000422 -0.00177 0.001178 0.004742 0.001474 -0.00446 0.002540 0.007957 0.003113 -0.00691 0.004197 0.010927 0.005211 -0.00851 0.006071 0.013467 0.007652 -0.00999 0.008165 0.015643 0.010323 -0.01135 0.010483 0.017704 0.013152 -0.01264 0.013030 0.019879 0.016139 -0.01389 0.015811 0.022154 0.019301 -0.01508 0.018835 0.024476 0.022664 -0.01622 0.022111 0.026761 0.026253 -0.01731 0.025649 0.028961 0.030095 -0.01837 0.029465 0.031089 0.034217 -0.01944 0.033588 0.033176 0.038650 -0.02055 0.038050 0.035274 0.043429 -0.02179 0.042889 0.037415 0.048594 -0.02310 0.048150 0.039598 0.054196 -0.02430 0.053889 0.041815 0.060295 -0.02559 0.060170 0.044056 0.066963 -0.02697 0.067070 0.046322 0.074285 -0.02841 0.074673 0.048624 0.082360 -0.02989 0.083078 0.050977 0.091295 -0.03143 0.092396 0.053394 0.101211 -0.03304 0.102739 0.055875 0.112220 -0.03475 0.114216 0.058417 0.124421 -0.03657 0.126920 0.061009 0.137892 -0.03847 0.140908 0.063636 0.152664 -0.04043 0.156184 0.066279 0.168699 -0.04244 0.172683 0.068905 0.185893 -0.04446 0.190278 0.071480 0.204087 -0.04646 0.208804 0.073971 0.223096 -0.04841 0.228080 0.076346 0.242734 -0.05026 0.247934 0.078581 0.262834 -0.05199 0.268218 0.080657 0.283256 -0.05358 0.288814 0.082559 0.303889 -0.05501 0.309631 0.084277 0.324650 -0.05627 0.330604 0.085802 0.345477 -0.05733 0.351683 0.087130 0.366320 -0.05820 0.372831 0.088253 0.387137 -0.05885 0.394024 0.089166 0.407892 -0.05927 0.415244 0.089859 0.428550 -0.05943 0.436476 0.090323 0.449085 -0.05931 0.457704 0.090541 0.469484 -0.05886 0.478918 0.090488 0.489771 -0.05799 0.500108 0.090133 0.510019 -0.05666 0.521265 0.089465 0.530312 -0.05450 0.542374 0.088485 0.550725 -0.05145 0.563421 0.087205 0.571326 -0.04797 0.584389 0.085655 0.592135 -0.04424 0.605264 0.083865 0.613113 -0.04037 0.626027 0.081853 0.634189 -0.03645 0.646650 0.079623 0.655303 -0.03256  0.667108 0.077168 0.676424 -0.02874 0.687379 0.074464 0.697531 -0.02504 0.707461 0.071456 0.718613 -0.02148 0.727394 0.068082 0.739663 -0.01809 0.747256 0.064333 0.760679 -0.01490 0.767132 0.060216 0.781658 -0.01191 0.787118 0.055791 0.802590 -0.00916 0.807259 0.051142 0.823469 -0.00666 0.827545 0.046328 0.844285 -0.00443 0.847934 0.041385 0.865025 -0.00250 0.868375 0.036329 0.885672 -0.00089 0.888806 0.031148 0.906204 -0.00038 0.909142 .0.025820 0.926601 0.001259 0.929270 0.020327 0.946842 0.001709 0.949048 0.014670 0.966910 0.001672 0.968387 0.008868 0.986803 0.001029 0.987348 0.003181 1.000000 0.000000 1.000000 0.000000

The natural laminar flow airfoil for a small jet of the present invention by the configuration as described above can reduce the fuel consumption rate by applying a resistive airfoil to travel at low cost to the aircraft operator and passengers, it is effective to reduce the consumption of fossil fuel.

Hereinafter, an embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings. In adding reference numerals to components of the following drawings, it is determined that the same components have the same reference numerals as much as possible even if displayed on different drawings, and it is determined that they may unnecessarily obscure the subject matter of the present invention. Detailed descriptions of well-known functions and configurations will be omitted.

1 is a perspective view of a general small jet, Figure 2 is a cross-sectional view illustrating the AA 'cross section of the airfoil, Figure 3 is a cross-sectional view of the airfoil according to an embodiment of the present invention.

4 is a comparison graph of the aerodynamic characteristics of the airfoil and the NLF0115 airfoil of the present invention, Figure 5 is a graph of the transition point position of the airfoil and NLF0115 airfoil of the present invention.

First, the terms and structures of the small jet and the structure of the airfoil are described to describe the present invention.

Referring to FIG. 1, a general small jet 100 is as shown in FIG. 1, and the small jet 100 includes a six-seater small jet engine cruising at a maximum speed of Mach 0.6 at a cruise altitude of 10 km. Means onboard aircraft.

1 and 2, the airfoil 300 (hereinafter Karifoil) is applied to the airfoil 200 of the small jet 100. The airfoil 300 is formed between a leading edge 210 and a trailing edge 220 formed with a space from the front edge 210 and between the front edge 210 and the rear edge 220. The upper surface 240 and the lower surface 250 are included. The airfoil 300 (hereinafter Karifoil) is reflected in increasing the performance and efficiency of the small jet 100.

Lifting ratio refers to the ratio of the lift (Lift) and drag (Drag) received by the airfoil (200). Alternatively, the drag ratio may be expressed as the ratio of the lift coefficient and the drag coefficient. This is expressed as follows.

2, the code length (c) means the maximum horizontal length of the cross section of the Karifoil (300). In addition, thickness-ratio is defined as thickness t / code length c at any position of the Karifoil 300.

In general, the thickness ratio should be high for the manufacture of the internal structure. However, when the thickness ratio is increased, the performance of the airfoil 200 such as the lifting ratio is reduced. Therefore, there is a compromise between thickness ratio and structural design of airfoil. In general research results, the thinner the thickness of the airfoil 200, the better the performance, but too thin is known to be more than 12% is appropriate because of problems in the fabrication and structural strength of the internal structure.

Accordingly, the average thickness ratio of the Karifoil (300) of the present invention is set to 12 to 13% and designed the airfoil shape, the maximum thickness ratio is 14 to 16% at the point where the maximum thickness ratio is present on the protest line 230 (210) From 50 to 60% point. This has the effect of delaying the transition of the flow on the upper surface 240 and the lower surface 250, by moving the maximum thickness ratio point to the rear more than 40% of the existing NLF-0115, The drag coefficient at the lift coefficient of 0.3 was 0.0034, about 12% less than the 0.0039 of NLF-0115, which reduced fuel consumption during operation.

Reynolds number refers to a general dimensionless coefficient used to represent hydrodynamic operating conditions.

로 설정하였다.Operation Reynolds number refers to the operating conditions of the Karifoil (300) according to the wind speed, the Karifoil (300) of the present invention, when the speed of a typical small jet Mach (Mach) 0.6 (Mach 1 = 1200 Km / h), driving The range of Reynolds numbers is preferably

Set to.

Referring to FIG. 2, a camber (Mean Camber Line) 260 is present in the airfoil cross-sectional shape of the aircraft. The camber 260 is a line connecting an intermediate point between the upper surface 240 and the lower surface 250 of the airfoil from the front 210 to the rear 220.

Referring to FIG. 3, the Karifoil 300 of the present invention makes the bending of the camber 260 somewhat larger than the existing natural laminar airfoil so that the drag bucket covers a wide lifting range.

Referring to FIG. 3, the Karifoil 300 of the present invention has a shape of a top surface 240 and a bottom surface 250 that are specially designed. The detailed shape thereof is shown in Table 1. Both y_upper / c and y_lower / c in the table are dimensionless values by the length of the protest line 230.

x / c y_upper / c x / c y_lower / c 0.000000 0.000000 0.000000 0.000000 0.000085 0.000873 0.000028 0.000160 0.000297 0.001902 0.000422 -0.00177 0.001178 0.004742 0.001474 -0.00446 0.002540 0.007957 0.003113 -0.00691 0.004197 0.010927 0.005211 -0.00851 0.006071 0.013467 0.007652 -0.00999 0.008165 0.015643 0.010323 -0.01135 0.010483 0.017704 0.013152 -0.01264 0.013030 0.019879 0.016139 -0.01389 0.015811 0.022154 0.019301 -0.01508 0.018835 0.024476 0.022664 -0.01622 0.022111 0.026761 0.026253 -0.01731 0.025649 0.028961 0.030095 -0.01837 0.029465 0.031089 0.034217 -0.01944 0.033588 0.033176 0.038650 -0.02055 0.038050 0.035274 0.043429 -0.02179 0.042889 0.037415 0.048594 -0.02310 0.048150 0.039598 0.054196 -0.02430 0.053889 0.041815 0.060295 -0.02559 0.060170 0.044056 0.066963 -0.02697 0.067070 0.046322 0.074285 -0.02841 0.074673 0.048624 0.082360 -0.02989 0.083078 0.050977 0.091295 -0.03143 0.092396 0.053394 0.101211 -0.03304 0.102739 0.055875 0.112220 -0.03475 0.114216 0.058417 0.124421 -0.03657 0.126920 0.061009 0.137892 -0.03847 0.140908 0.063636 0.152664 -0.04043 0.156184 0.066279 0.168699 -0.04244 0.172683 0.068905 0.185893 -0.04446 0.190278 0.071480 0.204087 -0.04646 0.208804 0.073971 0.223096 -0.04841 0.228080 0.076346 0.242734 -0.05026 0.247934 0.078581 0.262834 -0.05199 0.268218 0.080657 0.283256 -0.05358 0.288814 0.082559 0.303889 -0.05501 0.309631 0.084277 0.324650 -0.05627 0.330604 0.085802 0.345477 -0.05733 0.351683 0.087130 0.366320 -0.05820 0.372831 0.088253 0.387137 -0.05885 0.394024 0.089166 0.407892 -0.05927 0.415244 0.089859 0.428550 -0.05943 0.436476 0.090323 0.449085 -0.05931 0.457704 0.090541 0.469484 -0.05886 0.478918 0.090488 0.489771 -0.05799 0.500108 0.090133 0.510019 -0.05666 0.521265 0.089465 0.530312 -0.05450 0.542374 0.088485 0.550725 -0.05145 0.563421 0.087205 0.571326 -0.04797 0.584389 0.085655 0.592135 -0.04424 0.605264 0.083865 0.613113 -0.04037 0.626027 0.081853 0.634189 -0.03645 0.646650 0.079623 0.655303 -0.03256  0.667108 0.077168 0.676424 -0.02874 0.687379 0.074464 0.697531 -0.02504 0.707461 0.071456 0.718613 -0.02148 0.727394 0.068082 0.739663 -0.01809 0.747256 0.064333 0.760679 -0.01490 0.767132 0.060216 0.781658 -0.01191 0.787118 0.055791 0.802590 -0.00916 0.807259 0.051142 0.823469 -0.00666 0.827545 0.046328 0.844285 -0.00443 0.847934 0.041385 0.865025 -0.00250 0.868375 0.036329 0.885672 -0.00089 0.888806 0.031148 0.906204 -0.00038 0.909142 .0.025820 0.926601 0.001259 0.929270 0.020327 0.946842 0.001709 0.949048 0.014670 0.966910 0.001672 0.968387 0.008868 0.986803 0.001029 0.987348 0.003181 1.000000 0.000000 1.000000 0.000000

4 is related to the aerodynamic characteristics of the conventional NLF-0115 natural laminar flow airfoil developed by Dan Somers and the Karifoil (300) of the present invention is to compare the drag coefficient (Cd) according to the lift coefficient (Cl). As shown in FIG. 4, the Karifoil 300 has a smaller drag force than the NLF-0115 and a wider resistive area, which is advantageous in cruising and rising flight.

FIG. 5 relates to the position of the transition point and shows the position of the transition point according to the angle of attack in percent on the protest line 230. As shown in FIG. 5, the Karifoil 300 has a transition point located further behind the NLF-0015 on the top surface and a drag point behind the transition point at the angle of attack 0.5 degrees or less on the bottom surface.

Hereinafter, the operation of the present invention configured as described above will be described with reference to the drawings.

As shown in FIG. 3, when the Karifoil 300 of the present invention is applied to the airfoil 200 of the small jet 100, the transition point generated in the airflow flowing through the surface of the airfoil 200 is moved backward. The drag generated in the airfoil 200 may be reduced. This can result in increased maneuverability, increased flight limits and reduced fuel consumption.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may appropriately define the concept of terms in order to best explain their invention in the best way possible. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that the present invention. Therefore, the embodiments described in the present specification and the configuration shown in the drawings are only the most preferred embodiments of the present invention, and do not satisfy all of the technical idea of the present invention, and various equivalents may be substituted for them at the time of the present application. It should be understood that there may be water and variations.

1 is a perspective view of a typical small jet.

2 is a cross-sectional view illustrating a cross-section AA ′ of an airfoil.

3 is a cross-sectional view of the airfoil according to the embodiment of the present invention.

Figure 4 is a graph comparing the aerodynamic characteristics of the airfoil and NLF0115 airfoil of the present invention.

Figure 5 is a graph of the transition point position of the airfoil and NLF0115 airfoil of the present invention.

<Description of the symbols for the main parts of the drawings>

100: small jet

200: airfoil 210: leading edge

220: trailing edge 230: chord

240: upper side 250: lower side

260: Camber (Mean Camber Line)

300: airfoil

Claims (4)

In the natural laminar flow airfoil (300) for the small jet 100, The airfoil 300 is applied to the airfoil 200 of the small jet 100, and includes an upper surface 240 having a curved curved surface on the upper surface, and a lower surface 250 formed on the lower surface, The airfoil (300) is a natural laminar flow airfoil for a small jet, characterized in that to delay the transition of the flow in the upper surface (240) and the lower surface (250). The method of claim 1, The airfoil 300 has a maximum thickness ratio of 14 to 16%, the point where the maximum thickness ratio is 50 ~ 60% point from the front line 210 on the protest line 230, characterized in that for small jet natural laminar flow. The method of claim 1, The airfoil 300 has a driving Reynolds number

Natural laminar flow airfoil for small jets. The method of claim 1, Profiles of the upper surface 240 and the lower surface 250 are defined in x / c when a distance from the front 210 to the rear 220 along the protest line 230 is x / c . that define the top coordinate value y_upper / c and the lower surface coordinates y_lower / c and, formed by the upper surface coordinates (y_upper / c) and a lower surface coordinates (y_lower / c) corresponding to the table below, based on the x / c Characteristic natural laminar flow airfoil for small jets. x / c y_upper / c x / c y_lower / c 0.000000 0.000000 0.000000 0.000000 0.000085 0.000873 0.000028 0.000160 0.000297 0.001902 0.000422 -0.00177 0.001178 0.004742 0.001474 -0.00446 0.002540 0.007957 0.003113 -0.00691 0.004197 0.010927 0.005211 -0.00851 0.006071 0.013467 0.007652 -0.00999 0.008165 0.015643 0.010323 -0.01135 0.010483 0.017704 0.013152 -0.01264 0.013030 0.019879 0.016139 -0.01389 0.015811 0.022154 0.019301 -0.01508 0.018835 0.024476 0.022664 -0.01622 0.022111 0.026761 0.026253 -0.01731 0.025649 0.028961 0.030095 -0.01837 0.029465 0.031089 0.034217 -0.01944 0.033588 0.033176 0.038650 -0.02055 0.038050 0.035274 0.043429 -0.02179 0.042889 0.037415 0.048594 -0.02310 0.048150 0.039598 0.054196 -0.02430 0.053889 0.041815 0.060295 -0.02559 0.060170 0.044056 0.066963 -0.02697 0.067070 0.046322 0.074285 -0.02841 0.074673 0.048624 0.082360 -0.02989 0.083078 0.050977 0.091295 -0.03143 0.092396 0.053394 0.101211 -0.03304 0.102739 0.055875 0.112220 -0.03475 0.114216 0.058417 0.124421 -0.03657 0.126920 0.061009 0.137892 -0.03847 0.140908 0.063636 0.152664 -0.04043 0.156184 0.066279 0.168699 -0.04244 0.172683 0.068905 0.185893 -0.04446 0.190278 0.071480 0.204087 -0.04646 0.208804 0.073971 0.223096 -0.04841 0.228080 0.076346 0.242734 -0.05026 0.247934 0.078581 0.262834 -0.05199 0.268218 0.080657 0.283256 -0.05358 0.288814 0.082559 0.303889 -0.05501 0.309631 0.084277 0.324650 -0.05627 0.330604 0.085802 0.345477 -0.05733 0.351683 0.087130 0.366320 -0.05820 0.372831 0.088253 0.387137 -0.05885 0.394024 0.089166 0.407892 -0.05927 0.415244 0.089859 0.428550 -0.05943 0.436476 0.090323 0.449085 -0.05931 0.457704 0.090541 0.469484 -0.05886 0.478918 0.090488 0.489771 -0.05799 0.500108 0.090133 0.510019 -0.05666 0.521265 0.089465 0.530312 -0.05450 0.542374 0.088485 0.550725 -0.05145 0.563421 0.087205 0.571326 -0.04797 0.584389 0.085655 0.592135 -0.04424 0.605264 0.083865 0.613113 -0.04037 0.626027 0.081853 0.634189 -0.03645 0.646650 0.079623 0.655303 -0.03256  0.667108 0.077168 0.676424 -0.02874 0.687379 0.074464 0.697531 -0.02504 0.707461 0.071456 0.718613 -0.02148 0.727394 0.068082 0.739663 -0.01809 0.747256 0.064333 0.760679 -0.01490 0.767132 0.060216 0.781658 -0.01191 0.787118 0.055791 0.802590 -0.00916 0.807259 0.051142 0.823469 -0.00666 0.827545 0.046328 0.844285 -0.00443 0.847934 0.041385 0.865025 -0.00250 0.868375 0.036329 0.885672 -0.00089 0.888806 0.031148 0.906204 -0.00038 0.909142 .0.025820 0.926601 0.001259 0.929270 0.020327 0.946842 0.001709 0.949048 0.014670 0.966910 0.001672 0.968387 0.008868 0.986803 0.001029 0.987348 0.003181 1.000000 0.000000 1.000000 0.000000

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