PL242489B1 - Lifting rotor blade spar with variable twist angle - Google Patents

Abstract

The spar of the main rotor blade with a variable angle of twisting is characterized by the fact that inside the blade there is a spar consisting of a vertical beam (2a) and a horizontal beam (2b) connected to it in its central part. The middle part of the upper crossbar (2c) is connected to the upper end of the horizontal beam (2a) with a deformable connection, while the lower crossbar (2d) is connected to the lower end of the vertical beam (2a) with a deformable connection in the middle. At the same time, between the extreme ends of the horizontal beam (2b) and the upper crossbar (2c) and between the extreme ends of the horizontal beam (2b) and the lower crossbar (2d) there are elements made of shape memory material (1a, 1b, 1c, 1d). Shape memory elements (1a, 1d), (1b, 1c) located on one side of the horizontal beam (2a) are mounted on a guide (3a, 3b) and each of the guides (3a, 3b) is mounted in a hole located in horizontal beam (2b).

Description

Description of the invention

The subject of the invention is a main rotor blade spar with a variable twist angle, in particular for helicopter main rotors.

So far, blades made of metal girders covered with a composite, wooden blades, metal blades or composite blades are known. In addition, available blades are rectangular or tapered. They can also be twisted linear, double-linear or non-linear. There are various ways to increase the aerodynamic performance of rotorcraft by modifying their rotor blades.

Active Control Rotor Blade and Active Twist Rotor Blade technologies are mainly described in scientific publications. From the publication of M. Miller, J. Narkiewicz, W. Kania, T. Czechyra, "The Application of Helicopter Rotor Blade Active Control Systems for Noise and Vibration Reduction and Performance Improvement" no. 184, pp. 164-180, there are known construction solutions for "intelligent" rotors (Smart Rotor) through the use of piezoelectric elements in the active control of the blades. These elements are installed inside the blade structure as piezo-actuators or piezo-composites. It is possible to control the angle of inclination of the additional flap (at the trailing edge or blade tip) or to deform a fragment of the blade in order to twist it. Active control of the blade can apply to its fragment or its entire length. In the work of J.J. Epps, I. Chopra, "In-flight tracking of helicopter rotor blades using shape memory alloy actuators" Smart Mater. Struct., vol. 10, no. 1.2001, the concept of using SMA wires as elements reinforcing the load-bearing structure of a helicopter blade was described. In Lachenal, S. Daynes, and P. M. Weaver, "Review of morphing concepts and materials for wind turbine blade applications" Wind Energy, vol. 16, pp. 283-307, 2013, attention was paid to the research conducted so far and the consequences of the use of intelligent materials, namely the reduction of the aerodynamic drag of the blades, the reduction of noise and vibration, but also the possibility of turbulence. The possibility of reducing torsional loads on helicopter blades with piezoelectric actuators by 10% was indicated. The lack of moving parts and the simplification of the structure are important.

Patent application US 2017036752 (A1) discloses an active propeller blade with a shape memory alloy. The exemplary blade includes a propeller body, a plate coupled to the propeller body, a torque transmitting member, and a shape memory alloy (SMA) actuator. The SMA actuator has a far end and a proximal end. The distal end of the SMA actuator is attached to the torque transmitting element. The proximal end of the SMA actuator is connected to the propeller body. The SMA is configured to apply torque to the proximal end of the torque transmitting member as a consequence of the heat generated to the SMA. The SMA actuator is wrapped with a heating coil, which causes it to deform.

US 6,220,550 (B1) describes a device for deforming and moving aerodynamic or hydrodynamic surfaces, including rotor blade surfaces. The elements are bent and locked in one of at least three stable positions, in which the device, and thus the aerodynamic or hydrodynamic surfaces, are held by the force generated by the elastic deformation of the bent members. Since bending elements are always elastically deformed, the device snaps between discreet, stable positions and is firmly held in each of them. In another embodiment, more bending elements may be used to provide additional stable positions. In one application, the active device is used as a trailing lip tab for a helicopter rotor blade or tail rotor for vibration damping. The device can be operated manually or electrically using shape memory alloy wires to fasten the flex members in their various stable positions.

US Patent No. 6,135,713 (A) discloses an actively steerable helicopter rotor blade comprising a trailing edge flap actuated by a high-speed actuator. A lightweight, robust, fast-acting actuator suitable for use as a flap actuator consists of a pair of column actuators made of a smart material, such as piezoelectric, magnetostrictive, shape memory alloy, or other material that exhibits a change in shape when exposed to an external stimulus. Each of the column actuators consists of multiple piezoelectric ceramic elements connected together into single columns. The differential voltage applied to the columns causes differential extension of the column cylinders, which causes the cylinder tube to rotate around an axis perpendicular to the tips of the column cylinders. The movement of the actuator tube is coupled by the connection to the rotor blade flap. Spherical joints are positioned between the column cylinders and the cylinder tube to prevent significant bending loads being transferred to the column cylinders, and a center support is also provided for each column cylinder to limit the amount of acceleration due to bending loads, which would otherwise lead to failure due to bending loads stretching of the ceramic elements of the actuator.

From the patent description No. PL 208709 (B1) a wind turbine blade and a method of assembling a laminated blade profile are known, the essence of which is that the beam has at least one first part and at least one second part. The first part has at least one body part connected to at least one mounting surface and to at least one support wall. The parts are matched by means of height adjustment and connected to each other by mounting surfaces, and laminated profiles are mounted around the beam and glued to the respective support walls.

The essence of the main rotor blade spar with a variable twist angle, having a spar, blade filling, elements made of shape memory material, is that inside the blade there is a spar consisting of a vertical beam and a horizontal beam connected to it in its central part. The middle part of the upper crossbar is connected to the upper end of the vertical beam by a deformable connection, while the lower crossbar is connected to the lower end of the vertical beam by a deformable connection in the middle part. Between the extreme ends of the horizontal beam and the upper crossbar, and between the extreme ends of the horizontal beam and the lower crossbar, there are elements made of shape memory material. The shape memory elements located on one side of the horizontal beam are mounted on a guide, and each of the guides is mounted in a hole located in the horizontal beam.

The advantageous effect of the variable-angle main rotor blade spar according to the invention is that it allows each section to be controlled separately (independently). Such a blade is universal in terms of adjusting the shape (twist angle) to the flight phase (hovering, flight at cruising speed, etc.), which directly increases the operability of the rotorcraft using the proposed solution. The variable-angle main rotor blade spar, especially for helicopter main rotors, enables optimization of the lift-to-drag ratio to maximize aerodynamic excellence. Optimization of aerodynamic features allows to reduce the loads generated cyclically by the rotor, depending on the phase of flight. This will have a particularly significant impact on the effect of detachment of air streams from the blade surface in progressive flights. Reducing the amplitudes of variable loads significantly increases the fatigue strength of the structure, and thus reduces the weight of cooperating assemblies, such as pushers, fixed and rotating rings of the swash plate. The use of properly programmed metastructures of shape memory materials will reduce the power demand, thus increasing the range of the aircraft and/or extending the hovering time.

The object according to the invention is explained in more detail in an embodiment in the drawing, in which the individual figures show:

Fig. 1 - an isometric view of the spar with the bearing wing, Fig. 2 - the cross-section of the blade with the spar, Fig. 3 - the cross-section of the spar in the entry position, Fig. 4 - the cross-section of the spar in the deformed position.

The spar of the main rotor blade with a variable twist angle in the embodiment consists of a vertical beam 2a and a horizontal beam 2b connected to it in its central part. The middle part of the upper crossbar 2c is connected to the upper end of the vertical beam 2a by a deformable connection, while the lower crossbar 2d is connected to the lower end of the vertical beam 2a by a deformable connection in the middle part. Between the extreme ends of the horizontal beam 2b and the upper crossbar 2c, and between the extreme ends of the horizontal beam 2b and the lower crossbar 2d, there are elements made of shape memory material 1a, 1b, 1c, 1d in the form of a spring made of a metallic nickel and titanium alloy. The shape memory elements on the side of the leading edge of the rotor blade 1a, 1d, located on one side of the horizontal beam 2a, are mounted on the guide 3a. Elements with shape memory on the side of the trailing edge of the rotor blade 1b, 1c located on one side of the horizontal beam 2a and are mounted on the guide 3b.

The principle of operation of the device according to the invention is that by changing the temperature of the elements made of material with shape memory 1a, 1b, 1c, 1d, the girder 2 consisting of a horizontal beam 2b,

EN 242489 Β1 of the vertical beam 2a, the upper crossbar 2c and the lower crossbar 2d undergo twisting. The shape memory material elements 1a and 1c show the properties of a compression spring by connecting them to the power supply, while the shape memory material elements 1d and 1b show the properties of a tension spring. The upper crossbar 2c is deformed from its original position by being pushed away from the horizontal beam 2b on the side of the memory element 1a and attracted by the other end on the side of the memory element 1b. While the upper crossbar 2c is pushed away from the horizontal beam 2b, the lower crossbar 2d is attracted by one end towards the memory material element 1d and repulsed by the other end towards the memory material element 1c. By using elements of the shape memory material 1a, 1b, 1c, 1d with different characteristics and properties, as well as by diversifying their supply, the blade is twisted along its length. The shape memory elements 1a, 1d and 1b, 1c located on one side of the horizontal beam 2a are mounted on the guides 3a, 3b, which connect the upper crossbar 2c and the lower crossbar 2d, thus ensuring their change of position by the same angle. Each of the guides 3a and 3b is mounted in an opening located in the horizontal beam 2b.

Claims (1)

1. A spar of a main rotor blade with a variable twist angle, having a spar, blade filling and elements made of shape memory material, characterized in that inside the blade there is a spar (2) consisting of a vertical beam (2a) and a beam connected to it in its central part of the horizontal beam (2b), and the middle part of the upper crossbar (2c) is connected to the upper end of the vertical beam (2a) by a connection of the Iny m shape, and the lower crossbar (2d) is connected to the lower end of the vertical beam (2a) by a deformable connection in the middle part ), where between the extreme ends of the horizontal beam (2b) and the upper crossbar (2c) and between the extreme ends of the horizontal beam (2b) and the lower crossbar (2d) there are elements made of shape memory material (1a, 1b), (1c , 1 d), where the shape memory elements (1a, 1 d), (1b, 1 c) located on one side of the horizontal beam (2a) are mounted on the guide (3a), (3b), and each of the guides ( 3a), (3b) is seated in the hole z located in the horizontal beam (2b).