OA16837A - Ultrasonic sensor parking bollard - Google Patents

Abstract

The vertical oscillating movement wind turbine consists of three parts which are the convergent, the airfoil and the electrical generation system. The convergent accelerates the air which subsequently creates a lift force on a curved profile or a wing or blade. This force produces a translational movement in one direction and then the airbrakes are deployed to create a force in the other direction. This induces an oscillating movement which makes it possible to drive an electric generator. Wind can be a significant source of electrical energy production. The main technique to extract this energy is the use of a rotor with horizontal or vertical axis having a rotary movement. However, this configuration contains in itself the reasons for its inefficiency to a certain degree. The oscillating vertical wind turbine offers more efficiency and is more viable as a wind power generation technique.

Description

The present invention relates to a vertical wind turbine with oscillatory movement technically characterized by three parts which are the convergent, the airfoil, and the electrical generation system which, when they come into synergy, make it possible to provide mechanical energy transformed into electrical energy.

We know that until now there are wind turbines, mainly those with rotary motion which although fulfilling the same function as the wind turbine with oscillatory motion, object of the invention, present a certain number of technical problems which are among others:

- The low efficiency of the blade due to the need to twist it and the excess weight due to the reinforcement of the internal structure of the blade.

- The high speed at the tip of the blade resulting in the production of noise and the need to install a braking system to prevent cases of overspeed;

- The creation of a vortex at the end of the blade;

- Nuisances to the visual environment (danger for birds, difficulty in integrating into residential areas, damage to the ecosystem).

- The investigation of the state of the art known to the inventor in the field which is the subject of the invention has made it possible to identify the sources of scientific and technical information, particularly in the field of patents.

IVENTION PATENTS

- Device for producing energy from the driving force of the wind

W02008107411

- Folding vertical axis turbine

W02008104060

- Vertical wind turbines and methods of actuating them

W02008088921

- Vertical axis wind turbine comprising guiding devices

W02007010551

- Vertical axis wind turbine

WO03044362

- Wind turbine with axis of rotation perpendicular to the wind

FR2974860

- Method and device improving the operation of vertical lift wind turbines, by passive control of the incidence of the wings with decreasing amplitude.

FR2548740

- Profile for the manufacture of vertical wings for axial vertical wind turbines.

EP2610482

- Modular structure for tower for wind turbines and for other uses

EP 1645701

- Vertical axis wind turbine floating module method and system

WO2011049843

Examination of the state of the art, especially in the area of patents, has not made it possible to identify wind turbines which make it possible to solve the above problems, contrary to the object of the present invention: Vertical wind turbine with oscillatory movement

DESCRIPTION

The function of the vertical oscillating motion wind turbine is to produce electricity with great efficiency. This can be done with any moving fluid and in particular with air or water.

I. STATE OF THE PRIOR ART

Different types of oscillating wind turbines have been proposed to meet the challenge of efficiently extracting energy from a moving fluid. WO 2012/058761 A1 uses the oscillation of a wing close to a wall to take advantage of the ground effect (WIG effect) and thus increase the lift force. This ground effect can also be produced by using another wing nearby during the swinging motion. However, the need to have a close surface to use the ground effect has the consequence of greatly limiting the distance of the oscillatory movement. The swinging wing does not have time to accelerate to gain sufficient speed and thus generate great power. In addition, the use of ground effect requires induced drag which in turn will oppose the translational movement of the wing.

DE 10 2011 116464 A1 proposes to use the characteristic of destruction of lift for a rotor of the H-Darrieus type. However, the rotational movement of the rotor limits the power that can be extracted from a moving fluid.

Likewise, WO 2011/017594 A1 proposes the use of wings with a symmetrical profile, the angles of incidence of which are reversed after a certain translation distance to change the direction and thus create an oscillation movement. However, wings with a symmetrical profile have a lower lift coefficient than wings with a non-symmetrical profile. Therefore the lift force produced is less and the oscillation movement is small.

Also these oscillatory motion wind turbines are fixed on a rail which is perpendicular to the direction of the moving fluid. So to change the direction of movement, the translational speed of the wing at the end of the rail must be reduced to zero. This decreases the power that can be extracted. In addition, when the wings or blades of these wind turbines begin to translate, the direction of the fluid relative to the wing changes and the angle of attack must be adjusted. Despite this adjustment, the lift force is no longer aligned with the rail and it is a reduced component of the lift force that is exerted on the moving wing to translate in the direction of the rail.

The vertical oscillating motion wind turbine described below overcomes the problems discussed above. It can be divided into three parts which are the convergent, the airfoil and the electrical generation system (see board).

II. REALIZATION OF THE INVENTION

A. THE CONVERGENT

The convergent is an entry and exit corridor for air.

It is made with any material (wood, iron, aluminum) and is intended to speed up the circulation of air in the hallway.

To demonstrate this, consider a convergent having only one inlet and one outlet in a stable fluid flow. So the mass of air entering is equal to the mass of air exiting per unit time. Consequently:

• = m ₂ => / 7] xx K, = p ₂ xx K ₂ "

w,: represents the amount of mass per unit of time passing through the input "

ni,: represents the quantity of mass per unit of time passing through the outlet p: represents the density of the fluid

A: represents the fluid passage surface

V: represents the speed of the fluid

When the air flow speed is only 30% of the speed of sound, it can be considered an incompressible fluid (the density is constant). Let's check if this scenario is applicable to our case.

The speed of sound can be expressed as follows for air:

a = ^ yRT with / = ^ c _p : represents the quantity of specific heat of air at constant pressure c _v : represents the quantity of specific heat of air at constant volume

At room temperature and at a pressure equal to one atmosphere, this ratio is approximately equal to 1.4.

m ²

R: represents the specific constant of the gas in question and R _alr = 287 ₂

S hk

T: represents the temperature in Kelvin (K)

Thus for air having a temperature of 20 ° C or 293K, the speed of sound is equal to 345.45m / s. The maximum speed at which air could be considered to be an incompressible fluid is 103.6m / s. So the analysis of the fluid as being incompressible is acceptable as a method of resolution if the air speed in the convergent is less than or equal to 103m / s. So the density variable can be simplified in the equation below:

A - A 4 ^{x -} A ^{χ 1} - J ^A 1

The interest of the convergent thus lies in the increase of the air speed by reducing the area of the section.

The lift force created by the wing is a function of the speed squared.

₃

L = c, x - xdx V x 5 ¹ 2 c,: represents the coefficient of lift according to the profile of the wing in question and its angle of attack

S: represents the characteristic surface of the wing profile

To triple the speed of the air is to multiply by 9 the force generated for a wing. Therefore one wing can do the job of nine similar ones. On the other hand, the phenomenon of development of the boundary layer on the walls of the convergent can reduce the efficiency of the system because of the turbulent flow. Thus the use of traps for the boundary layer as well as a honeycomb to decrease the turbulent flow and rectify it respectively will be studied.

B. THE LOADING SAIL

The profile of the airfoil of the device is divided into two parts. The upper surface which is the upper part and the lower surface which is the lower part. On this upper part there is a depression due to the curvature while on the lower part there is an overpressure.

This pressure differential creates a load-bearing force perpendicular to the relative wind. The wing chord connects the foremost point of the wing (leading edge) to the rearmost point (trailing edge). The angle between the relative wind direction and the chord is called the angle of attack. The coefficient of lift defined instead is a function of this angle of attack. The higher this angle, the greater the force created up to a limit called the stall. When stalling, we witness a separation of the boundary layer which subsequently creates, because of the oscillatory movements of the air mass, vibrations called "buffeting". This regime should be avoided when designing the wind turbine, however the angle of attack must be as large as possible to generate the maximum amount of work.

The airfoil is made up of two linked wings, with their intrados facing each other, and having an airbrake on their extrados making it possible to destroy the lift force. These airbrakes are synchronized so that there is only one open at any time t of

16837 translation. When one airbrake is open for one wing, the other airbrake, on the other wing, is closed. The airbrakes are linked to servo controls controlled by a microcontroller. Sensors are placed to determine when along the way the airbrake should be deployed or retracted. The power supply comes from the electric generator of the wind turbine itself because the electrical power extracted from the process is far greater than the power required to operate the speed brakes.

The wing is constantly maintained at the angle of attack to produce maximum lift via a servo control controlled by the microcontroller. A pitot tube and an accelerometer are installed respectively on the wall of the corridor upstream of the lifting airfoil and on the airfoil. This makes it possible to know the two components of speed and to deduce the angle of attack from them. This angle is displayed by the microcontroller via the airfoil servo control. The airfoil is made of composite materials to have the lightness that will achieve high travel speed.

The airfoil is mounted on a rail or guide. This rail or guide with two semi-circular sections making it possible to change the direction of translation of the two wings without the need to bring the translation speed to zero and two straight sections on which the translational movement of the airfoil takes place. This rail or guide is mounted on a pivot axis at its center and a servo control allows it to be moved horizontally. Thanks to the knowledge of the speed vector extracted via the Pitot tube and the accelerometer, the rail or guide pivots to constantly align the direction of translation with the lift force or the aerodynamic resultant. Thus a high translational speed can be achieved and therefore a high power can be produced because:

P = FxV

P: power;

F: translational force;

V: speed of translation.

This rail is made of metal to withstand large accelerations at the circular sections and to minimize the coefficient of friction. The airfoil is linked with ball bearings with the rail or guide. Thus the wind turbine seen from the front oscillates despite the adjustment of the rail even if the trajectory seen from above is a curve

16837 non-circular due to the superposition of the translational movement and the adjustment of the rail or guide.

C. ELECTRICAL GENERATION SYSTEM

The power generation system consists of a permanent magnet neodymium generator. This generator makes it possible to produce electricity from low rotational speeds and therefore from a low translational speed. Traditional generators must reach high rotational speeds to start producing power. The advantages of the low angular speed generator are lower costs, reduced maintenance, simple design, reliable power generation and several models are available.

The electric generator is mounted along the vertical axis. At the end of the generator shaft is a toothed metal disc. The generator is fixed on a horizontal platform with play to adjust to the movement of the rail or guide. On the rail or guide is attached a metal strap (like bicycle chains); linked to the airfoil; having the same contour as the rail or guide and on which the toothed disc of the generator is nested.

[II. OPERATION

The convergent accelerates the airflow which then exerts a lift force on the wing with the airbrake closed. The other wing with the airbrake open does not produce lift force in the opposite direction. The rail servo control adjusts the rail to constantly align the travel direction with that of the lift force. In translational motion, at the start of a semicircular section, the closed airbrake is opened and the other that was open is closed, thereby changing the direction of the lift force. The airfoil continues to translate to the next circular section and the cycle is repeated. The rail or guide continuously adjusts via its servo control to align with the direction of the lift force or aerodynamic resultant. The translation of the airfoil sets in motion the belt which turns the toothed disc of the generator. So the generator is rotated to produce electricity.

The implementation of the invention makes it possible to solve the problems identified.

Claims (7)

1. Regarding the low efficiency of the pale Since the blade or wing has a translational movement, the angle of attack is the same everywhere on the profile so there is no need to twist the wing. Certainly the oscillatory movement 16837 decreases the angle of attack, however this decrease is homogeneous along the blade and can be easily compensated because the translation speed is low. 2. Regarding the high speed at the end of the blade 170 This wind turbine, having no rotary motion, is not affected by this wing tip speed phenomenon. In addition, the wing is enclosed in walls and the little noise produced is damped avoiding any noise pollution. 3. Concerning the creation of vortex at the end of the blade 175 Of course, the wing experiences the same phenomenon of overpressure and depression, however the vortices cannot develop because they are stopped by the upper and lower walls. 4. Regarding the nuisance to the visual environment This wind turbine is completely covered and the whole system has a cubic shape. 180 This aesthetic form can be enhanced to participate in the image of the city. In addition, the slow movement of the wing and the honeycomb installed at the air inlet ensure that there is no damage to the ecosystem. 1. Vertical wind turbine with oscillatory movement and not of rotation, characterized in that it consists of two wings linked with their intrados facing each other and having on their extrados an airbrake making it possible to destroy the lift force. These speed brakes are synchronized so that there is only one open at any time t. When one airbrake is open (a) for one wing, the other airbrake on the other wing is closed. 2. Vertical oscillating motion wind turbine according to claim 1 characterized in that the wing is constantly maintained at the angle of attack to produce the maximum lift via a servo control controlled by a microcontroller. A Pitot tube (e) and an accelerometer are respectively installed on the wall of the corridor upstream of the airfoil and on the airfoil. This allows us to know the two components of speed and to deduce the angle of attack. This angle is displayed by the microcontroller via the airfoil servo control. 3. Vertical wind turbine with oscillatory movement characterized in that the airfoil is mounted on a rail or guide (d). This rail or guide has two semi-circular sections allowing the direction of translation of the two wings to be changed without the need to bring the translation speed to zero and two straight sections on which the translational movement of the two wings takes place. 4. Vertical oscillating motion wind turbine according to claim 3 characterized in that this rail or guide (d) is mounted on a pivot axis in its middle and a servo control allows it to be moved on the horizontal plane (f). Thanks to the knowledge of the speed vector extracted via the Pitot tube (e) and the accelerometer, the rail or guide pivots to constantly align the direction of translation with the lift force or the aerodynamic resultant. 5. Vertical oscillating motion wind turbine according to claim 1, 3 and 4 characterized in that the electric generator (b) is mounted along the vertical axis and having at the end of its shaft a toothed metal disc (c) which is nested in a belt linked to the airfoil and having the same contour as the rail or guide. The generator is fixed on a horizontal platform (g) having play to adjust to the movement of the rail or guide (h). 6. Vertical oscillatory motion wind turbine according to claims 1, 2, 3, 4 and 5 characterized in that several stages of two wings are placed one after the other to extract the residual power of the fluid from the preceding stage. 7. Vertical oscillatory motion wind turbine according to claims 1, 2, 3, 4, 5 and 6 characterized in that it can be used for any fluid and produce mechanical or electrical or hydraulic energy.