DE102013103588A1 - rotor blade - Google Patents

Abstract

The invention relates to a rotor blade (1), in particular for helicopters, which has a front edge (4) and a rear edge (5) which extend in the longitudinal direction between a blade connection (2) and a blade tip (3), with a profile (7 ) with an area of maximum profile thickness (d1, d2) between the front edge (4) and the rear edge (5). In order to achieve high maneuverability with a good distribution of lift force, a distance (a1, a2) between the area (6) of maximum profile thickness and the front edge (4) decreases in one direction from the blade connection (2) to the blade tip (3).

Description

The invention relates to a rotor blade, in particular for helicopters, which has a leading edge and a trailing edge, which extend in the longitudinal direction between a blade connection and a blade tip, wherein it has a profile with a region of maximum profile thickness between the leading edge and the trailing edge.

Such a rotor blade is used in particular in connection with Modellhubschraubern and there especially in the field of aerobatics. As a rule, such rotor blades have an at least substantially convex profile, wherein a region of maximum profile thickness is usually pronounced closer to the front edge than to the rear edge. In this context, the profile is always referred to as the cross-sectional profile of the rotor blade, which extends perpendicular to its longitudinal axis.

To generate lift, the rotor blades rotate at a generally variable angle of attack about a driven hub. For the rotor blades are usually attached with their blade connection via a swash plate on the hub. By adjusting the swash plate can then adjust the angle and thus the buoyancy.

In addition to the use as a lifting screw, so to generate buoyancy, rotor blades are used in lifting screws as a tail rotor and are used there for torque control and for adjusting the direction of flight

The invention is based on the object of providing a rotor blade which enables high maneuverability and allows long flight times. Especially for model helicopters in the field of art or in the 3D flight area, these properties are in great demand.

According to the invention this object is achieved by a rotor blade having the features of claim 1. Advantageous embodiments can be found in the subclaims 2 to 10.

According to the invention, it is thus provided that a distance between the region of maximum profile thickness and the front edge decreases in one direction from the blade connection to the blade tip. The profile thickness corresponds to a distance between an upper side and a lower side of the rotor blade. Usually, the area of maximum profile thickness runs at a constant distance from the leading edge, whereas it is now provided according to the invention to reduce the distance in the direction of the blade tip. Thus, a pressure point of the rotor blade moves depending on the distance to the blade terminal and is closer to the leading edge in the area adjacent to the blade tip than in the vicinity of the blade terminal. This design has positive effects on the maneuverability. Due to the greater distance of the region of maximum profile thickness to the leading edge in the vicinity of the blade connection, a relatively high flight stability is achieved, while at the same time a high maneuverability is made possible by the reduction of the distance in the direction of the blade tip. In this case, the different inflow velocity is taken into account during rotation of the rotor blade by the displacement of the maximum range. This results in a uniform lift distribution over the blade length and thus a more uniform material load. At the same time, fluttering of the leaf tips is hardly to be expected, even in extreme flight conditions. In addition, with strong interception maneuvers a swinging of the helicopter nose is minimized.

Preferably, the distance decreases linearly. Seen along the longitudinal direction of the rotor blade, the areas of the maximum profile thickness are thus on a line which more and more approximates the leading edge. Sudden changes in the profile thickness or the position of the area of maximum profile thickness do not occur.

In a preferred embodiment, it is provided that an amount of the maximum profile thickness decreases from the blade connection to the blade tip. The amount of the maximum profile thickness corresponds to the maximum distance between the top and bottom of the rotor blade. The rotor blade thus tapers toward the blade tip, for example by 10 to 20 percent, in particular by 10 to 15 percent or up to a maximum of 12 percent. This results in a reduced sheet resistance and thus a reduction of flow losses or an extension of flight times.

It is particularly preferred that a percentage thickness reserve remains constant in the longitudinal direction. A percentage thickness reserve means the ratio of the distance of the area of maximum profile thickness to the front edge with respect to the amount of the maximum profile thickness. With a uniform reduction of the sheet thickness, the distance between the front edge and the area of maximum profile thickness thus decreases by the same factor. Thus, a uniform lift distribution over the entire length of the rotor blade is achieved with reduced control forces, which is associated with low noise due to low turbulence.

In a preferred embodiment, the rotor blade has a rectangular shape. The trailing edge and the leading edge thus run parallel to each other. This avoids a pressure point migration at different angles of attack.

The profile of the rotor blade can be designed, for example, as a symmetrical profile or as a semi-symmetrical profile. In a symmetrical profile, the top and bottom of the rotor blade on an identical, convex profile. In a semi-symmetrical profile top and bottom are also convex, the underside but thinner overall. This buoyancy is generated even at an angle of 0 °. A symmetrical profile is particularly suitable for the art and 3D flight, because both in a normal position and in a supine position of the helicopter lift can be generated to the same extent, since this is only dependent on the angle of attack. By a semi-symmetrical profile, however, a better efficiency is achieved, which is associated with a lower energy consumption and thus longer flight times. Semi-symmetrical profiles are less suitable for aerobatics, however, since less buoyancy can be generated in the supine position than in the normal position.

It is also possible not to form the profile exclusively convex, but also to provide concave areas, in particular following the area of maximum profile thickness.

Preferably, the rotor blade comprises a composite material. This makes it possible to form the rotor blade very stable and at the same time with a low weight. The composite material used is preferably carbon fiber composite material, which in particular has an aramid reinforcement. The aramid reinforcement provides protection against tearing of individual parts, for example in the event of breakage of the rotor blade. Very stable and at the same time very light rotor blades can be produced with a carbon fiber composite material, which can be adjusted very precisely to the respective requirements, in particular with regard to rigidity and damping behavior.

It can be provided that the profile of the rotor blade has a styrofoam core. The Styoporkern has only a very small mass and causes a damping in particular of sound emissions.

A preferred length of the rotor blade is between 50 millimeters and 10 meters, in particular between 100 millimeters and 1000 millimeters. The rotor blade thus essentially serves for use with model missiles such as model helicopters and there especially for flying extreme maneuvers.

The invention will be described in more detail below with reference to a preferred embodiment in conjunction with the drawings. Herein show:

1 a top view of a rotor blade,

2 a side view of the rotor blade,

3 a cross-sectional profile of the rotor blade in the region of the blade connection and

4 a cross section of the rotor blade in the area of the blade tip.

In 1 is a rotor blade 1 shown in plan view. The rotor blade 1 has a leaf connection 2 and a blade tip 3 and a leading edge 4 and a trailing edge 5 on. The leading edge is running 4 and the trailing edge 5 parallel to each other in this embodiment, the rotor blade 1 So it has a rectangular shape. A width b of the rotor blade 1 So stays over its length l except in the area of the blade connection 2 and in the area of the blade tip 3 constant.

The rotor blade 1 is fully trained. In operation thus corresponds to an angle of attack in the area of the blade connection 2 an angle of attack in the area of the blade tip 3 ,

The leaf connection 2 serves to fix the rotor blade 1 on a rotor blade, for example via a swash plate. In operation, the rotor blade rotates 1 then around the rotor blade not shown, with the blade tip 3 due to the greater distance to the rotor blade scar moves faster than the area of the blade connection 2 , This results in different flow velocities.

A dash-dot line symbolizes an area 6 a maximum profile thickness, ie an area in which a distance between an upper side 8th and a bottom 9 of the rotor blade 1 is maximum. It can be seen that the area 6 the leading edge 4 approaches. In other words, taking a distance between the area 6 the maximum profile thickness and the leading edge 4 towards the blade tip 3 down. The course of the area of maximum profile thickness lies on a line that does not, as usual, parallel to a longitudinal axis of the rotor blade 1 extends but which extends at an angle thereto. The angle is for example in the range between 1 ° and 15 °. A pressure point of the rotor blade 1 thus shifts with increasing distance to the blade connection 2 towards the front edge. At the same time, the rotor blade tapers 1 in the direction of the leaf tip 3 , the amount of the maximum profile thickness thus decreases.

This is illustrated by the sectional views of a profile 7 of the rotor blade 1 that is near the leaf connection 2 has a maximum profile thickness d1 at a distance a1 to the leading edge, while a maximum profile thickness d2 at a distance a2 in the area of the blade tip 3 is trained. In this case, both the maximum profile thickness d1, d2 and the distance a1, a2 continuously decreases.

The decrease in the amount of the maximum profile thickness is, for example, also from 2 forth in which the rotor blade 1 is shown in side view. For example, the maximum profile thickness d1, ie the maximum distance between the top 8th and bottom 9 , near the leaf connection 2 about 10 millimeters, while the amount of the maximum profile thickness d2 adjacent to the blade tip is 8.5 millimeters. The rotor blade 1 Thus, it tapers continuously over its length l, which is, for example, in the range between 600 and 800 millimeters, while its width b is, for example, 50 to 70 mm and remains constant over the length l.

In the 3 and 4 are cross sections of the rotor blade 1 shown in FIG 3 the profile in the area of the blade connection 2 and in 4 the profile in the area of the blade tip 3 is shown. Both the thickness d1 of the area of the maximum profile thickness and its distance a1 to the front edge 4 are in the area of the leaf connection 2 of the rotor blade 1 greater than the corresponding distance a2 or the corresponding profile thickness d2 in the region of the blade tip.

A percentage thickness reserve remains constant. A ratio of the distance to the amount of the maximum profile thickness thus remains unchanged. Accordingly, the length l of the rotor blade applies 1 seen: a1 / d1 = a2 / d2.

The rotor blade shown 1 has a symmetrical profile, that is, an equal formation of the top side 8th and bottom 9 , It is also conceivable to transfer the principle to a semi-symmetrical rotor blade, in which the underside is thinner than the top. A displacement of the region of maximum profile thickness along the longitudinal direction of the rotor blade can also be provided in rotor blades whose shape deviates from a rectangular shape.

Due to the embodiment of the invention, a rotor blade is obtained, which can be used in particular for model helicopters in the field of art and 3D flight. Rotor speeds are usually between 1,900 and 2,600 revolutions per minute.

The rotor blade according to the invention allows a uniform lift distribution over the blade length and longer flight times, wherein control forces are reduced both on the swash plate and control servos. This results in a low noise and longer flight times. Even with extreme maneuvers, such as strong interception maneuvers and the like, this results in a stable attitude, in particular no aufschwingende helicopter nose, no fluttering of the blade tips and no torque drop of an engine is to be feared. At the very least, there are significant improvements over conventional rotor blades in terms of maneuverability as well as longer flight times through more efficient lift generation.

The invention is not limited to one of the above-described embodiments, but can be modified in many ways.

Rotor blades are not only used in helicopters or rotorcraft, but also in neighboring technical fields such as wind turbines. Although a preferred field of application of the present invention is in the field of model helicopters and in particular in the field of art and 3D flight, another use is also possible.

All of the claims, the description and the drawings resulting features and advantages, including design details, spatial arrangements and method steps may be essential to the invention both in itself and in various combinations.

LIST OF REFERENCE NUMBERS

1

rotor blade

2

blade connection

3

blade tip

4

leading edge

5

trailing edge

6

Area

7

profile

8th

top

9

bottom

a1, a2

distance

d1, d2

maximum profile thickness

b

width

l

length

Claims (10)

Rotor blade ( 1 ), in particular for helicopters, having a leading edge ( 4 ) and a trailing edge ( 5 ) extending longitudinally between a blade terminal ( 2 ) and a blade tip ( 3 ), where there is a profile ( 7 ) with a region of maximum profile thickness (d1, d2) between the leading edge ( 4 ) and trailing edge ( 5 ), characterized in that a distance (a1, a2) between the region ( 6 ) maximum profile thickness and the leading edge ( 4 ) in one direction from the leaf connection ( 2 ) to the blade tip ( 3 ) decreases. Rotor blade according to claim 1, characterized in that the distance (a1, a2) decreases linearly. Rotor blade according to claim 1 or 2, characterized in that an amount of the maximum profile thickness (d1, d2) of the blade connection ( 2 ) to the blade tip ( 3 ) decreases. Rotor blade according to one of the preceding claims, characterized in that a percentage thickness reserve remains constant in the longitudinal direction. Rotor blade according to one of the preceding claims, characterized in that the rotor blade ( 1 ) has a rectangular shape. Rotor blade according to one of the preceding claims, characterized in that the profile ( 7 ) is designed as a symmetrical profile or as a semi-symmetrical profile. Rotor blade according to one of the preceding claims, characterized in that it comprises a composite material. Rotor blade according to claim 7, characterized in that the composite material is formed as a carbon fiber composite material, wherein the rotor blade in particular has an aramid reinforcement. Rotor blade according to one of the preceding claims, characterized in that the profile has a styrofoam core. Rotor blade according to one of the preceding claims, characterized in that it has a length between 50 mm and 10 m, in particular between 100 mm and 1000 mm.

Images