FR2883047A3 - Wind energy conversion device, has blades with principal longitudinal dimension which extends along rotational axle and along length of blade, where blade forms rectangular panel with longitudinal slit for creating air passage - Google Patents

Abstract

The device (10) has a base (12) and a horizontal rotational axle on which blades (20) are mounted, where the blades acquire the kinetic energy of wind. Each blade has a principal longitudinal dimension which extends along the axle and along the length of the blade. The blade forms a rectangular panel with a longitudinal slit for creating an air passage. Eight blades are distributed in a regular manner around the axle to form a rotor.

Description

DEVICE FOR CONVERTING WIND ENERGY ENEIRGY

ELECTRIC OR NIECANIC

  The invention relates to a device for converting the wind energy generated by the wind force into electrical or mechanical energy, and more particularly to a horizontal axis wind turbine providing electrical energy.

  For centuries, devices have been used to capture the kinetic energy of the wind and convert it into energy that can be used by humans. The mills thus transform the force of the wind blowing into their blades into a mechanical energy that can be used, for example, to grind grain. Small finned turbines like those still existing in the western United States have also been used to pump water with the force of the wind.

  In recent decades, and especially for ecological reasons, wind turbines have developed rapidly to the point of becoming a source of electrical energy increasingly interesting in terms of cost and performance, as well as extremely low impact on the environment, that is to say in terms of air pollution. Their operation is also relatively simple. When it begins to blow, the wind exerts a system of forces on each blade which forms the rotor or the propeller of the wind turbine. The rotor, mounted most often in an external nacelle, then begins to rotate about its substantially horizontal axis of rotation. Moreover, an alternator, for example induction, is associated with the axis of the rotor. This alternator, or generator, is responsible for transforming the rotation of the blades into energy so as to provide a stable frequency electric current that can possibly be stored in accumulators before being delivered, or be used immediately, especially to illuminate a city.

  The maximum efficiency of the wind turbine is obtained when the propeller is facing the wind, so perpendicular. On large wind turbines, a small wind vane / anemometer located on the side directs the pod to move to another direction when it detects that the wind has turned.

  The power of the wind turbine, i.e., the number of kilowatts it can provide, is determined by the blade-swept area corresponding in this case to a disk.

  The number of blades does not matter because two large blades can provide more power than three blades, the energy produced by the wind being proportional to the cube of the speed of said wind.

  The location of the wind turbine is also particularly important. It is best to place it in high wind areas, avoiding squalls in favor of a more regular stream. Wind turbines are therefore most often placed on hills, or have tall masts to capture the maximum draft. Some wind turbines can thus have a mast of more than 40 meters in height and blades of 30 meters wingspan, which is a major drawback to their establishment, especially because of the visual and sound pollution produced.

  As an alternative to traditional wind turbines with horizontal axis of rotation and rotor with two or three blades, there are also Darrieus type wind turbines with a vertical axis of rotation and two C-shaped blades extending from the top to the bottom of the mast. facing symmetrically with respect to said mast. This unidirectional principle has the advantage of capturing winds wherever they come from, without the need for an orientation mechanism. However, this type of wind turbine is very fragile and requires very large dimensions (more than 100 m high) to produce enough electricity. In addition, in the lower part of the mast, the winds are weak and a loss of efficiency is observed. In addition, a wind turbine of this type does not require an accompanying engine for the start-up phase. Moreover, the generator being placed at ground level, its change causes disassembly of the mast and blades, which is long, delicate and expensive. Finally, unsightly shrouds are needed to hold the mast.

  For all the reasons and disadvantages mentioned, current wind turbines are not entirely satisfactory. In addition, their electrical efficiency is still low which means to build more and larger and to place a large number to form a wind farm. This can lead to disfigurement of the landscape, significant design and construction costs due to the size of the blades and the mast or the weight of the basket. Aerological and nature and environmental impact studies are also long and costly because it is necessary to choose precisely the location of their location as well as their arrangement / orientation relative to each other. The issues of security and reliability are also to be taken into account. The wind turbine remains a machine very exposed to bad weather (ice, lightning, rain and strong winds) and the risks of breakage are not negligible. The life of a wind turbine must be at least 20 years to be profitable. Its maintenance is also complicated and expensive because the different parts are subject to strong mechanical or thermal stresses due to fluctuating and / or turbulent winds. Thus, the rotor blades can either attenuate or reinforce the oscillations and vibrations of the parts and cause cracks or even breakage of the mast and / or blades. Finally, the dynamic behavior and fatigue properties of both the materials used and the entire structure must be studied very early and accurately.

  Thus, the invention aims to solve at least some of these problems by proposing a wind turbine having a particular arrangement of the blades relative to their axis of rotation.

  More specifically, the present invention relates to a device for converting the wind energy generated by the wind force into electrical energy comprising at least one base and an axis of rotation on which is mounted at least one blade for capturing the energy wind kinetics, wherein the axis of rotation is substantially horizontal and the or each blade has a major longitudinal dimension extending along said axis of rotation and substantially along its length.

  In order to have a large wind catch area, each blade is substantially planar and has the shape of a quadrilateral.

  In order to improve the efficiency of each blade by combining air pressure on the upstream face and suction air on the downstream face, each blade forms a rectangular panel provided with a longitudinal slot forming an air passage.

  Advantageously, the slot is located, with respect to the axis of rotation, at a distance of between about one third and two thirds of the width of the blade.

  In order to channel the air passing through the device, an air guide frame surrounds the axis of rotation and each blade.

  Preferably, the frame has an inner casing comprising an upstream air inlet and a downstream air outlet, and an outer casing surrounding the inner casing so that at least one air passage zone from upstream to the downstream is formed between the inner casing and the outer casing.

  In order to optimize the circulation of air inside the chassis, a deflector is inserted into the inner casing and has an additional air passage.

  Advantageously, the device comprises eight blades distributed regularly around the axis of rotation to form a rotor.

  In order to integrate the device into its environment, the device is adapted to be placed at the bottom of a valley for example under a bridge, or to extend in height between two hills and form a bridge portion.

  Other characteristics, details and advantages of the invention will emerge on reading the description which follows, made with reference to the appended drawings, given by way of example, and which respectively represent: FIG. 1, a sectional view a device for converting the force of the wind into electrical energy in accordance with the present invention; FIG. 2 is a front view of the device of FIG. 1; FIG. blade of the device of the invention, and - Figure 4, a detailed sectional view of the blade of Figure 3.

  Figures 1 to 4 show a device 10 according to the present invention for converting the wind force into electrical energy, also called wind.

  This wind turbine 10 has a base 12 placed on the ground and constituted for example by concrete or metal uprights, 25 dimensions chosen depending on the location.

  The wind turbine also comprises a substantially horizontal axis of rotation 15 which extends along the base 12 and has a length L. Blades 20, eight in number in the present embodiment, stand perpendicular to the axis. 15 to provide a rotor 25. Each blade has a main longitudinal dimension I which extends along said axis of rotation, substantially all its length L. Each blade 20 is in the form of a substantially rectangular flat panel 22 . The blades 20 are identical and evenly distributed around the axis of rotation 15, that is to say each one 45 of one another.

  Each blade 20 has a longitudinal slot 24 located, relative to the axis of rotation 15, at a distance between one third and two thirds of the width h of the blade, for example to about half.

  The entire rotor 25 is surrounded by a frame 30 for example of plastic, composite, metal, or metal alloy. The frame 30 includes an inner casing 40 located closest to the blades 20, an outer casing 50 surrounding the inner casing 40 and supported by the base 12, and a deflector 60 located inside the inner casing 50. The outer casings and internal sectional sections have partially cylindrical to fit the outer shape of the rotor 15.

  A large upstream opening 42 is arranged in the outer casing 40 and a smaller upstream opening 52 is arranged in the inner casing 50 to act as air inlet mouths.

  Similarly, a wide downstream aperture 44 is provided in the outer casing 40 and a smaller downstream aperture 54 is provided in the inner casing 50 to act as air outlets.

  An air passage space 55 is arranged between the inner casing 40 and the outer casing 50, in the upper and lower part of the wind turbine 10.

  The deflector 60 has a curved shape complementary to an upper portion 41 of the inner casing. This deflector has an intermediate opening 62 acting as a secondary air outlet, and it defines an air passage 65 with a lower part 43 of the inner casing 40.

  The operation of the horizontal axis wind turbine 10 and longitudinal blades of the present invention is as follows.

  The air enters at the same time through the opening 42 of the inner casing 40 and the opening 52 of the outer casing 50. Two air currents are created, one passes through the rotor 25, the other passes through the passage 55 arranged between the two casings.

  The first stream of air, illustrated by the arrows A, enters the inner casing 40. Part of the air entering the inner casing 40 pushes the blades 20 one after the other according to the direction of rotation F of the rotor 25, as illustrated by the arrows Al, while another part of the air passes through each blade 20 at the longitudinal slot 24, as illustrated by the arrows A2. A suction phenomenon is also created behind each blade 20, partly because of the presence of the longitudinal slot 24.

  As the rotor 25 rotates within the inner housing 40, a portion of the airflow arrives at the opening 62 of the baffle 60, as illustrated by the arrow A3. This portion of the air flow then exits through the passage 65 arranged between the deflector 60 and the bottom wall 43 of the inner casing 40. The air flows having passed through the inner casing 40 exit from it at its downstream opening. 44, as illustrated by the arrow A '.

  The second stream of air, illustrated by the arrows B, passes through the frame 30 through the passages 55 arranged between the two casings, without ever entering the inner casing 40 and therefore without contact with the blades 20. This air created a small suction increasing the rotation of the blades 20 and thus improving the efficiency of the wind turbine.

  Finally, all the air flows meet at the downstream opening 54 of the outer casing 50 and escape into the nature.

  Of course, the rotor 25 is associated with an alternator (not shown) to generate electric current thanks to the rotational movement of the blades 20.

  Alternatively, the device according to the present invention can provide mechanical energy, for example for pumping water from a water table using for example a system of arms and connecting rods.

  Advantageously, the wind turbine 10 is disposed in a windy zone, preferably with a steady wind rather than squalls of force and appearance random. Thus, the wind turbine 10 can be placed at the bottom of a valley, for example under a bridge, or higher, between two hills, and possibly constitute a bridge portion.

  The advantages of this type of wind turbine are the following: - better distribution of forces on the blades, air suction effect thanks to the longitudinal slot, - high stability of the shaft to vibrations, and therefore continuity of movement rotation of the rotor, division of the air flow entering into different streams adding, a single blade on the eight is successively not active, resulting in a high yield, - resistance to strong wind squalls, - implantation easy crest or valley.

  It should be understood, however, that the detailed description, given solely by way of illustration of the subject of the invention, in no way constitutes a limitation, the technical equivalents also being included in the scope of the present invention.

  Thus, the number and / or shape of the blades may be different, as well as their distribution around the axis.

  Several slots can be arranged through each blade, be different between each blade, linear or adapted curvature.

Claims (9)

  1. Device (10) for converting wind energy generated by the wind force into electrical or mechanical energy comprising at least one base (12) and one axis of rotation (15) on which at least one blade is mounted (20). ) for sensing the kinetic energy of the wind, characterized in that the axis of rotation (15) is substantially horizontal and the or each blade (20) has a main longitudinal dimension (I) extending along said axis of rotation (15) and substantially along its entire length (L).   2. Device according to claim 1, wherein each blade (20) is substantially flat and has the shape of a quadrilateral.   3. Device according to claim 2, wherein each blade (20) forms a rectangular panel (22) provided with a longitudinal slot (24) to create an air passage (A2).   4. Device according to claim 3, wherein the slot (24) 15 is located, relative to the axis of rotation (15), at a distance between one third and two thirds of the width (I) of the blade (20).   5. Device according to any one of the preceding claims, wherein an air guiding frame (30) surrounds the axis of rotation (15) and each blade (20).   6. Device according to claim 5, wherein the housing has an inner housing (40) comprising an upstream air inlet (42) and a downstream air outlet (44), and an outer casing (50) surrounding the housing. internal (40) so that at least one upstream to downstream air passage (55) is formed between the inner housing (40) and the outer housing (50).   7. Device according to claim 6, wherein a baffle (60) is inserted into the inner housing and has an additional passage (62) of air.   8. Device according to any one of the preceding claims, characterized in that it comprises eight blades (20) regularly distributed about the axis of rotation (15) to form a rotor (25).   9. Device according to any one of the preceding claims, characterized in that it is adapted to be placed at the bottom of a valley for example under a bridge, or to extend in height between two hills and form a bridge portion .