FR2766241A1 - Wind turbine, - Google Patents

Abstract

The wind turbine is constructed with a vertical shaft (12) which carries several horizontal radial masts (3), in the form of a circle. At the end of each mast, are fitted two rods (2), to form a Y-shaped fork (1). Two rigid blades (4) are fixed to each fork, by means of hinges (6), which allow the blades to close together horizontally and then when the mast rotates into the wind, the blade are allowed to open to present the full surface area to the wind. The two rods fixed to the end of the masts are designated as return arms and each one carries a triangular sail (5), which lies between the return arm and the rigid blade. The sails are fixed on to the arms by means of pipes (8), which allow the sails to rotate around the return arms. The sails are so positioned and angled as to drive open the rigid blades due to the pressure of the wind on the sails as to masts rotate. Detailed descriptions of optimum angles for all fittings are provided.

Description

WIND TURBINE FOR GENERATOR
DESCRIPTION
The present invention, given by way of nonlimiting example, relates to a wind turbine device for a generator, which receives the force of the air flow horizontally and directly on a front surface, without steps.

 Devices are already known which make it possible to use forces generated by air displacements, either by propellers or by sail turbines.

 For example, devices which, traditionally effected the force of air currents using helices which by their steps, distance which separates two turns, transform a horizontal force into a rotary movement.

 These devices cause a significant pressure drop, a limitation of surface and pitch for optimum efficiency.

 Devices are also known which make it possible to transform the force of air currents by sail turbines but these control and arrangement systems, which are used to position the driving sails in search of the direction of the currents, are too complicated.

 In fact, to coordinate the movement of the sails, flexible cables, hauling pulleys, springs or control mechanisms are used which make the device ineffective due to friction and the effects of shock or braking, or other undesirable effects which cause considerable energy loss when positioning the sails.

 The invention aims, among other things, to solve the problems mentioned above. Thanks to the innovation of this simple and efficient system, used by the present invention, better flow is obtained, greater simplicity of arrangement of the wings and sails; it is thus possible to eliminate all the drawbacks due to the mechanical control systems employed in the known techniques.

 The device for generator, according to the present invention filed, is formed of a vertical shaft, which carries several horizontal masts radiated in the form of a circle.

 The invention has, as a first object, a method of fixing at the end of the spokes of the circle (which are carrying masts) of two metal rods in the form of V - which will be called subsequently the two return arms.

 These two return arms themselves form an opening angle of 600 to 90 "- the most favorable being an angle of 76, by the top of this angle the two return arms are fixed to the carrying masts.

 At the same time, the return arms must all be inclined in the same direction at an angle of 85 to 1300 with the corresponding carrying mast, the most favorable being an angle of 1020.

 The two return arms, fixed at the end of the carrying mast, must also be positioned so as to divide into two equal angles - their opening angle - relative to the horizontal plane containing the circle, drawn by the carrying masts.

 A steel rod must be fixed between the ends of the two return arms, in order to maintain the rigidity of these.

 A bearing mast is thus obtained with the two Y-shaped return arms, which will be called the Y-shaped fork.

 Subsequently, two rigid wings in the shape of a trapezoid or triangular are fixed to the carrying mast using articulations. Each wing has an angle, formed between the support mast and the triangular sail edge from 600 to 90, the most favorable being an angle of 750.

 To make the device more effective, a counterweight mechanism must be attached to the wings which allows the movement of the wings to be balanced and made more sensitive to the force of the wind.

 The joints used, will serve to the wings to open vertically and present their maximum surfaces to the wind and then, to close horizontally, when turning against the wind, taking a shape similar to an airplane wing (we say of to feather).

 To allow it to function in this way, an arrangement of the wings is carried out by triangular sails which are held by the return arms.

 Each triangular sail has an angle of 400 to 600, formed between the adjacent edge of a wing and a return arm, the most favorable being an angle of 450.

 The invention is now described in detail, and refers to the accompanying drawings.

 Figure 1 shows the fork composed of a carrying mast and two return arms.

 FIG. 2 represents the method of mounting the wings and sails on the fork.

 Figure 3 shows the power wings in the open position facing the wind.

 Figure 4 shows the same power wings in the closed position against the wind.

 FIG. 5 represents the detailed elements of the power wings.

 FIG. 6 represents all of the assembled wings and sails.

 FIG. 7 represents an embodiment of a wind turbine.

 FIG. 8 represents a possibility of mounting a turbine on several levels.

 Figure 9 shows the entire wind turbine seen from above.

 Figure 10 shows a vertical section of the entire device.

 FIG. 11 represents two sections of wind turbines which illustrate the arrangement of the sails and the wings activated by the force of the air currents.

 FIG. 12 represents a perspective view and the mode of operation of a wind turbine for a generator.

 In the figures drawn, we see wind turbines for generators which illustrate the different modes of construction and operation of the device.

 The use which is made of the device is not limited to the examples described in the figures. Thus, the invention can be applied in various fields.

 Fig. 1. shows a Y-shaped fork (1) composed of a carrying mast (3) and two return arms (2).

A steel rod or cable (7) must be attached to the ends of the two return arms, in order to maintain their rigidity. The supporting masts (3) could have a telescopic solution which will allow, by automatic adjustment, to adapt the elongation of the masts to the force of the wind.

 Fig. 2. represents the Y-shaped fork (1) with two wings (4) and two sails (5). The drawing also shows the plastic pipes (8)) glued with the triangular fabrics; this pipe (8) thus forms an edge of the triangular sail (5). The pipes (8) should be just slightly larger so that they can rotate freely on the return arms (2). This assembly if necessary may contain bearings for large sails.

 The wings (4) must be assembled with the triangular sails (5) along the adjacent edges. The canvas stretched over the wing (4) and the triangular sail (5) can form a unit. The free edge of the sail (5) of length (a) at the time of the circular movement of the wing (4) determines its extreme open positions.

 To assemble the sail (4) and the wing (5) with the fork (1), first, we slide the plastic pipe (7) on the return arm (2), then we fix the wing (4 ) to the carrying mast (3) using joints (6).

 Figs 3. and 4. show the fork (1) with the two wings (4) fixed, which close and open with the help of joints (6) each performing a quarter turn separately by pivoting around their horizontal axis towards the ends fixed by triangular webs (5) in connection with the return arms (2).

 The wind turbine for generator works by a simple rotary movement, autodirectional around its vertical axis (12). This wind turbine at the time of its rotation gradually brings its closed sails to an extreme point, where the face of the sails is facing the wind perpendicularly. At this point, under the force of the wind pressure, the sails open, causing the wings to open (fig. 3) and exposing themselves to the forces of the wind. the wind, they close to take the horizontal shape, similar to an airplane wing (fig. 4).

 This is very clearly visible on the vertical section of the turbine (fig. 10). On the left side, the wings are seen in a vertical position when the wind is taken (fig. 3). On the right side, we see the wings in a closed horizontal position, opposite, when turning against the force of the wind (fig. 4). The effect obtained allows maximum use of the force of the wind.

 In relation to the wings (4), a counterweight mechanism (10) must be fixed (fig. 4) which serves to give the right balance to the movement of the wings. The wings, in the event of zero wind, must go into the open position, however when turning against a light wind, they must go into the closed position.

 Fig. 5 shows a construction of the fork (1) composed of a carrying mast (3) and two return arms (2) with wings (4) in the shape of a trapezoid and triangular sails (5).

 For load-bearing masts (1), light metal tubes in narrowed form can be used.

 The return arms (2) can be made of steel rods or metal tubes depending on their length.

 The two return arms (2) and the head (9) for assembling to the support mast (3) can be made in one piece or separately, with a greater or lesser dimension of the return arms.

 The frames (11) are intended to build wings (4), they are made on the basis of tubular profiles made of duralumin or other synthetic materials with similar properties. The frames (11) maintained in the shape of a trapezoid, ensure the fixing of the stretched canvas or the fixing of to other very solid synthetic materials.

 The joints (6) fixing the wings to the supporting mast (3) can be fitted with bearings in the event of large wing dimensions.

 The plastic pipes (8) glued with the triangular fabrics, ensure their pivoting movement around the axes of the return arm (2).

 Fig. 6. represents the triangular sails (5), with the wings (4) in the shape of a trapezoid, which forms a fixed assembly on the fork (1).

 Figs. 7.8. and 9. represent non-limiting examples of the various embodiments of wind turbines and the possibility of increasing the force of the device.

 - fig. 7. by lengthening the supporting masts.

 - fig. 8. by mounting multi-stage turbines.

 - fig. 9. by fixing several equal forks at equal intervals according to the diameter of a construction which turns in circles.

 Figs. 10 and 11. show the vertical and horizontal section of the embodiment of a wind turbine device for a generator on a tower. In a preferential form we see, on the left side the wings (4) and the sails (5) in the open position at the time of the most favorable position for taking in the wind, on the right side opposite we see the wings ( 4) and the sails (5) in the closed position when turning against the force of the wind.

 The wings (4) and the sails (5) with the load-bearing forks (1) are fixed at equal intervals to the central load-bearing shaft (12), which is held by large rolling bearings (13), rotates around its axis vertical and works like a drive shaft.

 This shaft by means of a drive wheel (14) fixed to the bottom of the carrier shaft, drives by friction transmission of the alternators (16). They are fixed to the mobile carrier on the axis (15), which is used for switching on the alternators and which makes it possible to select their numbers providing electricity.

 The driving wheel (14) by its significant weight serves as a wind speed regulator and by its kinetic energy, it has the function of stabilizing the speed of movement of the turbine at the different wind forces.

 Fig. 12. represents the wind turbine for generator in perspective. We see on the left side the wings (4) and the sails (5) in an open vertical position at the time of the wind. On the right side, we see the wings (4) and the sails (5) in a closed horizontal position when turning against the wind. The forks (1) are fixed at equal intervals to the central shaft (12) which by the driving wheel (14), drives the alternators (16) to produce electricity.

 The wind turbine device for generator which uses the direct forces generated by the air currents, is intended to produce electricity in general, but more particularly for the charging stations of electric cars, caravan batteries , and heaters for large greenhouses. It can supply electricity in isolated places and on ships.

Claims (4)

REVANDICATION  1) Wind turbine device for generator, characterized in that it is formed of a vertical shaft (12), which carries several horizontal masts (3) radiated in the shape of a circle. The invention has, as a first object, a method of fixing at the end of the spokes of the circle, which are carrying masts (3), of two metal rods (2) in the form of V which will be called hereinafter both return arm (2). These two return arms (2) themselves form an opening angle of 60 to 900, the most favorable being an angle of 760. By the top of this angle, the two return arms (2) are fixed to the 'end of the supporting masts (3). At the same time, the return arms (2) must all be inclined in the same direction at an angle of 850 to 1300 with the corresponding carrying mast (3), the most favorable being an angle of 1020. The two return arms (2), fixed at the end of the carrying mast (3) must also be positioned so as to divide into two equal angles, their opening angle, relative to the horizontal plane containing the circle, drawn by the carrying mast (3 ), attached to the central support shaft (12). The supporting mast (3) with the two return arms (2) in the form of Y will be called the Y-shaped fork (1). Subsequently, two rigid wings (4) in the shape of a trapezoid, the wings (4) are fixed on the carrying mast (3). 4) may also have a triangular shape. Each wing (4) has an angle, formed between the supporting mast (3) and the adjacent edge of the triangular sails (600 to 90), the most favorable being an angle of 750. The articulations (6) used, will be used for wings (4) to open vertically and present their maximum surfaces to the wind and then, when turning against the wind, to close horizontally and to take a shape similar to an airplane wing, it is said to set flag. To allow it to function in this way, we proceed to the arrangement of the wings (4) by triangular sails (5). which by means of pipes (8) are held by the return arms (2). Each triangular sail (5) has an angle of 400 to 600 formed between the adjacent edge of a wing (4) and of a return arm (2), the most favorable being an angle of 45 ". The free edge of the sail (5) of length (a) at the time of the circular movement of the wing (4) determines its extreme open positions. The two wings (4) determine its extreme opening positions. The two wings (4) fixed on the fork (1) close and open by means of articulations (6) each performing a quarter turn separately by pivoting around their horizontal axis towards the ends fixed by sails triangular (5) in connection with the return arms (2). The wind turbine for generator works by a simple rotary movement, autodirectional around its vertical axis (12). This wind turbine at the time of its rotation gradually brings its closed sails (5) to an extreme point, where the face of the sails is in a direction perpendicular to the wind. At this time, under the force of the wind pressure, the sails (5) open, causing them to open the wings (4) and exposing themselves to the wind forces. After which, when turning against the wind, they close to take the horizontal shape, similar to an airplane wing. it is said to be feathered. Plastic pipes (8) glued with the triangular fabrics (5) ensure their pivoting movement around the axes of the return arm (2). The pipes (8) should be just slightly larger so that they can rotate freely on the return arms (2). This assembly, if necessary, may contain bearings for large sails (5). The two return arms (2) and the head (9) for assembling to the support mast (3) can be made separately, with large dimensions of the return arms (2). The wings (4) and the sails (5) with the carrying forks (1) are fixed at equal intervals to the central support shaft (12) which is held by large rolling bearings (13), rotates around its vertical axis and works like a drive shaft. This shaft by means of a drive wheel (14) fixed to the bottom of the carrier shaft (12), drives by friction transmission of the alternators (16). They are fixed to the mobile carrier on the axis (15), which is used for the engagement of the alternators (16), and which makes it possible to select their numbers providing electricity. The driving wheel (14) by its large weight serves as a wind speed regulator and by its kinetic energy, it has the function of stabilizing the speed of movement of the turbine at the different wind forces.  2) Wind turbine device for generator according to claim 1 characterized in that, relative to the wings (4) a counterweight mechanism (10) is applied which serves to give the right balance to the movement of the wings and make it more sensitive in the force of the wind. The wings in case of zero wind, must be in the open position, however when turning against a light wind, they must be in the closed position.  3) Wind turbine device for generator according to claim 1 or claim 2 characterized in that, one can apply to the device three solutions to increase the flow of the device by lengthening the protective masts (fig. 7.), by mounting turbines on several levels (fig. 8.), by fixing at equal intervals several load-bearing forks according to the diameter of a construction which turns in circles (fig. 9.).  4) Wind turbine device for generator according to claim 1 or claim 2 characterized in that, a steel rod (7) must be fixed to the ends of the two return arms (2), in order to maintain the rigidity of these- this.