RU2326787C2 - Method of controlling wing placed in fluid medium at its interaction with said medium and device to of its realisation - Google Patents

Abstract

FIELD: transportation.

SUBSTANCE: method of controlling the wing placed in the fluid medium at its interaction with the said medium consists in that the wing is arranged at an angle of attack, sufficient for the said interaction. The wing part is isolated by the stabiliser, given its not hinged mounting relative to an axis of rotation of the wing with the angle of attack outrunning the angle of attack in motion, and the wing is turned till stalling on the said wing part. The device intended for using this method has a fixed support connected to the beam via a movable linkage, a carriage hinged on to the latter, at least one wing and a drive. The device is provided with a plate pivoted on to the carriage and provided with a kinematics linkage with the wing, also pivoted on to the carriage. The drive is made so that to be supplied from an appropriate source. At least one wing part is isolated by the stabiliser, given its not hinged mounting relative to an axis of rotation of the wing with the angle of attack outrunning the angle of attack in motion, and the wing is turned till stalling on the said wing part. The wing and its part are provided with a dynamic force pickup connected in the drive electric circuitry via an amplifier. The drive can be controlled by programmed signals of the programming device connected in the drive electric circuit. Apart the wing part isolated by the stabiliser, one more wing part is isolated by the stabiliser and is turned relative to the axis of rotation the other side.

EFFECT: increase in wing speed and in aerohydrodynamic lift on it.

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Description

The invention relates to the fields of power engineering, aircraft manufacturing, shipbuilding, in particular to methods and devices that use working bodies placed in a fluid and moving in this fluid (wings, propellers, propellers, turbine wheels, etc.) of various aerodynamic or hydrodynamic devices, under the conditions of aerodynamic or hydrodynamic interaction of these working bodies with a fluid medium.

The invention can be widely used in the energy sector of a wind power station or hydroelectric power station, in aviation - aircraft propulsion devices (airplanes, helicopters, gyros, gyroplanes, etc.) or active flight control elements of aircraft, in water transport - propulsion devices or active underwater movement controls and surface ships of all types, as well as air-cushion ships, in industrial aerodynamics or hydrodynamics - fans, superchargers, compressors, pumps, in the industry of goods for sports, recreation, entertainment opinions, etc.

Terminology

Fluid - a physical substance (gas, liquid, suspension, metal, etc.) that has the property of fluidity.

The wing is a working body, i.e. the main structural element of aerodynamic or hydrodynamic devices, on which in the process of interaction with the fluid, a useful force, called lifting force, primarily arises.

The working trajectory of the wing is part of the trajectory of the wing, when a lifting force arises on the wing as a result of interaction with the flow.

In the known propulsion system, to create a driving force of the apparatus in a fluid medium, the wing is pivotally coupled to a drive rigidly mounted on the apparatus and imparting to the wing a reciprocating motion perpendicular to the fluid flow. The mover’s wing is equipped with an angle of attack control device made in the form of a wing-shaped element connected to this wing, having its own drive to control its angular position relative to the wing. This makes it possible to provide the required angles of attack of the wing, when it operates as a mover, in any modes of movement of the apparatus, since when the installation angle of the wing-shaped element changes, the position of the system changes - the wing with the wing-shaped element in the fluid flow. However, it is not disclosed how to control its own drive of the pterygoid element, namely, to change the installation angle of the pterygoid element. Obviously, the control is performed with the wing stopped, and the adjustment of the installation angle of the pterygoid element affects only the frequency of the oscillatory process and does not allow to establish the angle of attack of the wing during its translational movement. Thus, in the presence of one wing-shaped element with one own drive, the required angle of attack of the wing on the march is not ensured and the optimal ratio of the speed of movement of the wing to the flow rate of the fluid on the working path is not provided.

There are various methods for the interaction of a wing and a fluid in which a continuous flow of fluid around a wing is realized, for example, “A method for converting the kinetic energy of a fluid into reciprocating movement of a wing and an apparatus for its implementation” (see RF patent No. 21411058 C1). The method consists in the fact that when the wing is placed in a fluid and when it interacts with this medium, the wing is set at an angle of attack sufficient for the specified interaction. When moving the wing, the angle of attack is maintained constant by changing the angle between the wing chord and the fluid flow. Upon reaching the optimum ratio of the speed of movement of the wing and the speed of flow, the angle between the chord of the wing and the direction of flow is kept constant.

However, this method does not allow to obtain the best efficiency of the interaction of the wing with the fluid, because the presence of acceleration and braking sections does not allow to obtain a constant speed of movement of the wing, and the achieved constant angle of attack cannot be considered beneficial for the entire trajectory.

A device for controlling a wing placed in a fluid medium when interacting with this medium is also known from the RF patent No. 21411058 C1, it comprises a fixed support, a carriage beam movably connected to it, pivotally mounted on it at least one wing, drive unit. The device for setting the angle of attack is made in the form of a wing-shaped element with its own drive to control its angular position relative to the wing. This allows to obtain large angles of attack, which provides a significant increase in the efficiency of the conversion of the kinetic energy of the fluid into the reciprocating movement of the wing. However, the device for setting the angle of attack of the wing allows you to get the maximum angle of attack, and without allowing the flow to stall, only when the best ratio of the speed of the wing and the fluid is achieved, which, if achieved, is short-term and this does not provide a significant increase in efficiency along the entire working path wings.

The technical result of the invention is to automate the process of interaction of the wing with the fluid, obtaining at each point of the working path of the wing angle of attack the maximum possible, which ensures continuous flow of the wing around the wing of the fluid, providing the ability to control the angular position of the wing throughout the path, which increases the speed wing and aerohydrodynamic force on it.

The specified technical result is achieved by the fact that when implementing the method of controlling a wing placed in a fluid during its interaction with this medium, namely, that the wing is set at an angle of attack sufficient for the specified interaction, part of the wing is separated by a stabilizer when it is not articulated relative to the axis of rotation of the wing with an angle of attack ahead of the angle of attack of the wing during movement, and turn the wing until a stall of fluid flow occurs on this part of the wing, and then reduce Wing attack goal.

The above technical result is also achieved in that the device for controlling a wing placed in a fluid medium during its interaction with this medium, comprising a fixed support, movably connected beam-carriage, pivotally mounted on it at least one wing, a drive made with a plate pivotally mounted on the carriage and having a kinematic connection with the wing also pivotally mounted on the carriage, and the drive is configured to receive energy from its source and is connected to the plate at least , one part of the wing is separated by a stabilizer with a non-articulated installation relative to the axis of rotation of the wing so that when moving the angle of attack is always ahead of the angle of attack of the wing, the wing and part of the wing are equipped with dynamic force sensors that are included in the electric circuit of the drive by means of an amplifier.

In such a device, it is advisable to control the drive with the programmed signals of the software device included in its electrical circuit.

In such a device, in addition to the part of the wing separated by the stabilizer and rotated relative to the axis of rotation of the wing, another part of the wing can be separated by the stabilizer and can be rotated relative to the axis of rotation of the wing in the opposite direction.

The invention is illustrated by the accompanying drawings.

Figure 1 shows the wing in interaction with the fluid and the velocity vectors of the wing.

Figure 2, 3 provides drawings of the device according to the patented invention.

Figure 4 provides a block diagram of the control drive plate according to the patented invention.

The method of controlling a wing placed in a fluid, in its interaction with this medium is as follows.

A wing is placed in the fluid (FIG. 1), which is moved in the fluid to interact with it and, when controlled, is rotated around its longitudinal axis. The wing is moved, in one case, from the dynamic forces arising from the interaction with the fluid (when the wing is used to convert the energy of the fluid flow into useful energy), in the other case, due to the drive receiving energy from an external source (when the wing is used to creating a driving force). The wing is rotated around its longitudinal axis due to the dynamic force arising from the interaction with the fluid, and due to the drive receiving energy from an external source, thereby changing the angle of installation of the wing and obtain the desired angle of attack.

The wing is set at the starting angle of attack, the value of which is sufficient to start the interaction of the wing with the fluid, as a result of which an aerohydrodynamic force arises on the wing, and it moves. When the wing moves at an increasing speed, it is rotated, the angle of the wing is changed, the angle of attack of the wing is increased, and the rate of increase in turbulization of the fluid flow attached to the wing is controlled, preventing the flow of fluid attached to the wing from disruption by reducing the angle of attack of the wing by changing angle of installation of the wing, then again increase the angle of attack of the wing, this ensures an uninterrupted flow of fluid around the wing. As a result of this, with any change in the speed of movement of the wing, the angle of attack is maintained as high as possible during continuous flow of fluid around the wing, the angular position of the wing along the entire trajectory is controlled, which ensures an increase in the speed of the wing and aero-hydrodynamic force.

A device (see FIGS. 2 and 3) that implements the claimed method of controlling a wing placed in a fluid medium when it interacts with this medium comprises a fixed support 1 with a beam-carriage 2 movably mounted on it, on which at least pivotally mounted at least one wing 3, equipped with a dynamic force sensor 4, which converts the value of the dynamic force on it into an electrical signal (for example, a strain gauge installed in the place of attachment of the wing to its own axis). At least one part 5 of the wing 3 is separated by a stabilizer 6 with a non-articulated installation relative to the axis of rotation of the wing in such a way that when interacting with the fluid at any angle of attack, its angle of attack is always greater than the angle of attack of the entire wing 3 due to the articulated rotation of the part 5 of the wing from dynamic force, while the axis of rotation of the wing portion 5 is offset from the center of action closer to the leading edge. Part of the wing 5 is equipped with a dynamic force sensor 7, which converts the value of the dynamic force on it into an electrical signal. The wing 3 may include a part 8 separated by a stabilizer 6 and rotated relative to the axis of rotation of the wing, equipped with a dynamic force sensor 9 that converts the value of the dynamic force on it into an electrical signal, while part 5 is rotated relative to the axis of rotation of the wing in the other direction, part of the wing 5 and part 8 are fixed. On the beam-carriage 2 is mounted pivotally on its own axis, oriented along the fluid flow, the plate 10, having a kinematic connection with the axis of the wing 3, when the plate 10 is deflected, the wing 3 is rotated. To change its aero-hydrodynamic characteristics (for example, to change the area of interaction with the fluid), the plate 10 is equipped with its own drive 11, receiving energy from an external source. Sensors 4, 7 and 9 of the dynamic force and the actuator 11 are combined into a single electrical circuit, which includes a power source and a control unit.

The inventive installation operates as follows. The wing 3 and the plate 10 are placed in the fluid, and the fixed support 1 is fixed so that the wing 3 moves across the fluid flow. The wing 3 is set at a starting angle of attack to the fluid flow, it, the plate 10 and the carriage 2 are moved. When moving the plate 10, a dynamic force appears on it and the plate 10 deviates, the angular position of the wing 3 changes in the direction of increasing the angle of attack, while on part 5 earlier than on the wing 3, the effect of separation of the fluid flow attached to it arises, the dynamic force on it changes abruptly, the obtained value of the signal of the dynamic force sensor 7 installed on it is stored. The actuator 11 changes the aero-hydrodynamic characteristic of the plate 10 so that when the angular position of the wing 3 changes, the dynamic force sensor 4 mounted on the wing 3 shows the highest value, and the dynamic force sensor 7 installed on part 5 shows the achieved value. The stabilizers 6 do not allow mixing of the fluid flows attached to the wing 3 and to part 5. Upon reaching the extreme position, the wing 3 receives the opposite starting angle of attack and moves in the opposite direction. When using this device to control the wing 3 in constant load mode and constant fluid velocity, it is possible to control the actuator 11 with programmed signals of a software device included in its electrical circuit. When installed on the wing 3 of part 8, the actuator 11 is controlled by the signals of the sensors 4 and 7 when the wing 3 moves in one direction or by the signals of the sensors 4 and 9 when the wing 3 moves in the other direction. As a result of this, with any change in the speed of movement of the wing, the angle of attack is the maximum possible, and at the same time, disruption of the fluid flow connected to the wing is not allowed.

In the process of moving the wing, depending on the characteristics of the elements of the electric circuit (drive, sensors and control unit), the maximum advantageous angle of attack of the wing is maintained from the start values to values that are higher than critical values under steady-state flow conditions in known similar technical devices over the entire trajectory, which provides maximum wing speed and aero-hydrodynamic force on it.

Claims (4)

1. The method of controlling a wing placed in a fluid medium when it interacts with this medium, namely, that the wing is set at an angle of attack sufficient for the specified interaction, characterized in that part of the wing is separated by a stabilizer when it is not hinged relative to the axis of rotation of the wing with an angle of attack that is ahead of the angle of attack of the wing during movement, and turn the wing until a stall of fluid flow occurs on this part of the wing, after which the angle of attack of the wing is reduced. 2. Device for controlling a wing placed in a fluid medium during its interaction with this medium, comprising a fixed support, a beam-carriage movably connected to it, at least one wing pivotally mounted on it, an actuator, characterized in that the device made with a plate pivotally mounted on the carriage and having a kinematic connection with the wing, also pivotally mounted on the carriage, and the drive is configured to receive energy from its source and connected to the plate, at least one part of the wing is separated stabilizer when not mounted relative to the axis of rotation of the wing in such a way that when moving the angle of attack is always ahead of the angle of attack of the wing, the wing and part of the wing are equipped with dynamic force sensors, which are included in the electric circuit of the drive by means of an amplifier. 3. The device according to claim 2, characterized in that the drive is controlled by programmed signals of a software device included in its electrical circuit. 4. The device according to claim 2, characterized in that in addition to the wing part separated by a stabilizer and rotated relative to the axis of rotation of the wing, another wing part is separated by a stabilizer and rotated relative to the axis of rotation of the wing in the other direction.

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