FR2597161A1 - Device for raising the pylons (towers) of wind-powered pumping engines - Google Patents

Abstract

The invention relates to a device enabling the pylons (towers) of wind-powered pumping engines to be raised, so as to make it possible, without risk of collision between the feet of the pylon (tower) and the wheel, to: - decrease the distance between the wheel and the vertical axis of orientation of the wheel in order to reduce the gyroscopic torque around the vertical axis of orientation of the wheel, - increase the angle at the apex of the pylon (tower) in order to stretch across wells of large diameter and to decrease the cross-section of the feet of the pylon (tower), while providing the latter with sufficient resistance. The device according to the invention consists of a post 11 fitted with two fastening systems; the first fastening system 12, located at the base of the post, making it possible to fasten the post to the apex of the pylon (tower), the second fastening system 13, located at the apex of the post, making it possible to fasten the head of a wind powered engine to the post.

Description

 The present invention relates to a device making it possible to raise the pylons of pumping wind turbines so that a reduction in the distance between the wheel and its vertical axis of orientation is not hampered by risks of collision between the feet of the pylon and the wheel.

 Figure 1 schematically shows a conventional pumping wind turbine.

 A pumping wind turbine. conventional, as shown diagrammatically in FIG. 1, is made up of: - a wheel (li, with a horizontal axis, fitted with blades <2), driven by the wind, - a head (3) which supports the wheel, performs its guiding in rotation and transforms the rotational movement of the wheel into an alternative rectilinear translational movement of the rod or cable (for operating the t5i pump, this head being mounted on a vertical axis which allows the orientation of the wheel in the wind thanks to a rudder (6), - a pylon which raises the head to a certain height above the ground, and which supports the column (7i of tubes at the end of which is fixed the pump.

 A conventional pumping wind turbine tower as shown in Figure 1 generally has three or four feet (8) made of metal angles or metal tubes, fixed on concrete studs (9i anchored in the ground, which form with reinforcements 10, a trellis These legs are joined together, at their upper end, just under the head, at a distance from the axis of the wheel much less than the radius of the latter.

 The use of these conventional pylons as described above does not make it possible to optimally resolve three problems, which are - reducing the gyroscopic torque around the vertical axis of orientation of the wheel caused by the accelerations and decelerations of the wheel under the effects of the wind, this gyroscopic torque will be all the greater the further the wheel is from its vertical orientation axis; the gyroscopic torque modifies the orientation of the wind wheel, controlled by the rudder, and thus harms the efficiency of the wind turbine, - reduce the cross section of the pylon's feet, while ensuring that the latter withstands the horizontal forces applied to the wheel especially in stormy winds, - stepping over wells of large diameter with the pylon.

Indeed: - reducing the gyroscopic torque can only be done by reducing
1 inertia of the wheel or by reducing the distance between the latter and the vertical axis of orientation of the wheel; the wheel chosen, its inertia cannot be modified; reducing the gyroscopic torque can therefore only be done by reducing the distance between the wheel and the latter's orientation axis, that is, to avoid collisions between the wheel and the feet of the pylon, by reducing the angle at top of the latter, - reducing the cross-section of the feet while ensuring the resistance of the pylon to the horizontal forces applied to the wheel can only be done by reducing the forces in the feet, which can only be done by increasing the 'angle at the top of the pylon; this being accompanied, at constant pylon foot length, only by a negligible reduction in the height of the pylon; indeed, increasing by 19 angle at the top of the pylon, angle at the initial summit 12t and initial height 5.9 meters, halves the efforts in the feet, while reducing its height only by 26 centimeters, - stepping over wells of large diameters with a pylon of given height can only be made by increasing the angle at the top of the latter.

 With conventional pylons, reducing the gyroscopic torque can only be done by decreasing the angle at the top of the pylon. Reducing the section of the feet of the latter and stepping over wells of large diameters, can only be done by increasing the angle at the top of the pylon. A compromise, which does not optimally resolve all three problems, must therefore be made on the value of the angle at the top of the pylon.

 The device according to the invention makes it possible to remedy the three problems satisfactorily; in addition, it raises the wheel above the ground, which allows it to be placed in more favorable wind pickup conditions.

 FIG. 2 schematically represents the device according to the invention mounted on a conventional pumping wind turbine.

 The device according to the invention, as shown diagrammatically in FIG. 2, consists of a post (11) provided with two fixing systems, the first fixing system (12) allows the post to be fixed to the top of the pylon, the second fixing system <allows the fixing of a wind turbine head on the pole. The length of the post must be sufficient to be able to increase the angle at the top of the pylons without hindering, by risk of collision between the wheel and the pylon, a reduction in the distance between the wheel and the axis of orientation of this last.

 The comparison of a pumping wind turbine not fitted with the device according to the invention, as shown on fife 1, and a pumping wind turbine fitted with the device according to the invention, as shown in FIG. 2, makes it possible to identify the possibilities offered by the device according to the invention.

 Compared to the wind turbine not fitted with the device according to the invention, the wind turbine fitted with the device according to the invention has the following particularities: - the wheel is closer to the axis of orientation of the latter, thus, the gyroscopic torque is reduced, - at constant pylon foot length, the angle at the top of the pylon O: t larger, thus, the section of pylon feet is more reliable without reducing the resistance of the latter and the spanned wells are larger diameter, - the wheel is at higher altitude, therefore, in more favorable wind pickup conditions.

 According to a first embodiment, the device according to the invention consists of a tube having at its base, a system allowing its fixing on a pylon, and at its upper end a fixing system allowing to receive a wind turbine head .

 Figure 3 shows, in partial section, the first embodiment of the device according to the invention mounted on a pylon and supporting a wind turbine head.

 According to a first embodiment, the device according to the invention consists of: - a steel tube (14), - a circular plate (15), of the same diameter as the diameter of the tube, attached welded to the upper end of the latter and on which are used to fix, by screws, the vertical axis (16) (orientation of the wind turbine head. A hole (17) made in the center of this plate allows the passage of the rod or cable (18) for operating the pump.

- a square Gi9i plate with side length greater than the diameter of the attached tube welded to the lower end of the latter. A hole (20) made in the center of this plate allows the passage of the rod or the cable for operating the pump.

- four angles (21). each being woven at the level of its supports on a corner of the square plate and on a tube regenerator, come to cap the top of the pvlone r22). These holes practiced in these four angles allow the fixing, by bolts, of the device according to the invention on the top of the pylon.

 According to a second embodiment, the device according to the invention consists of a tube of non-constant section, this section crott from the base of the tube to its top. The result of the forces collected by the post being horizontal and its point of application being located above the post, the latter being recessed at its base, the bending moment in a section of the post will be all the greater as this section is near the recessed base of the post; this justifies the use of a post whose quadratic moment of inertia (ie by extension, the section) decreases as one approaches its sum t.

 Figure 4 shows, in partial section, the second embodiment of the device according to the invention mounted on a pylon and supporting a wind turbine head.

 According to a second embodiment, the device according to the invention consists of: - a conical tube <23) made of steel made by rolling from a flat sheet, the junction generator (24) being welded over its entire length , - a circular plate (25), of the same diameter as the upper diameter of the tube, attached welded to the upper end of the latter and on which is fixed, by screws, the vertical axis (26) of orientation from the head of the wind turbine. A hole (27) made in the center of this plate allows the passage of the rod or cable (28) for operating the pump.

- A square plate (29) of side length greater than the lower diameter of the attached tube welded to the lower end of the latter. A practical hole (30) in the center of this plate allows the passage of the rod or the pump control cable.

- four angles <31), each being welded to a corner of the square plate, come to cover the top of the pylon (32). Holes in these four angles allow the device according to the invention to be fixed by bolts to the top of the pylon.

 According to a third embodiment, the device according to the invention consists of a post composed of a wire mesh, of small overall size and of almost constant section, produced by assembling standard profiles.

 FIG. 5 represents, in partial section, the third embodiment of the device according to the invention mounted on a pylon and supporting a wind turbine head.

 According to a third embodiment, the salt device on the invention ect consisting of: - a metal structure, of square base, consisting of four vertical angles i33) connected ertre them by -es flat irons (34), the structure thus forming a trellis, a square plate (35) of side length equal to the length of the rib of the square base of the structure. attached welded to the upper end of the latter and to which is fixed by screws.

 the vertical axis <36) of orientation of the wind turbine head. A hole <37) made in the center of this plate allows the passage of the rod or cable (38) for operating the pump.

- A square plate (39) of side length greater than the length of the side of the square base of the attached structure welded to the lower end of the latter. A hole (40) made in the center of this plate allows the passage of the rod or the cable for operating the pump.

 - four angles; (41), each being welded at its supports on a corner of the lower square plate and on an edge of the structure.

come over the top of the pylon <42). Holes in these four angles allow the device according to the invention to be fixed by bolts to the top of the pylon.

 According to a fourth embodiment, the device according to the invention consists of a post composed of a wire mesh, the quadratic moment of inertia of which (by extension the section; decreases as we get closer to This metal mesh is made by assembling standard profiles.

 FIG. 6 shows, in partial section, the fourth embodiment of the device according to the invention mounted on a pylon and supporting a wind turbine head.

 According to a fourth embodiment, the device according to the invention consists of: - a metal structure, of square base, consisting of four angles (43i non-parallel whose overlapping ends are welded together; these four angles are connected between them by flat irons <44), the structure thus forming a lattice, - a square plate (45, attached welded to the upper end of the latter and on which is fixed, by screws, the vertical axis ( 46) orientation of the wind turbine head. A hole '47) made in the center of this plate allows the passage of the rod or cable (43) for operating the pump.

- A square plate (49) of side length greater than the length of the side of the square base of the attached structure welded to the lower end of the latter. A hole (50) made in the center of this plate allows the passage of the rod or the pump operating cable.

- four angles (51, each being welded to a corner of the square plate, cover the top of the pylon (52). Holes made in these four angles allow the device according to the invention to be fixed to the top of the pylon.

 Of course, various modifications can be made by those skilled in the art to the various embodiments of the device according to the invention, which have just been described by way of nonlimiting examples, without departing from the scope of the invention. ; these modifications can notably affect.

- on the wind turbine head fixing system which depends on the fixing possibilities of the latter (there is a fixing system by type of wind head, hence the impossibility of describing them all), - on the fixing system on the top of the wind turbine pylon which depends on the fixing possibilities on the latter (There is a fixing system by type of wind turbine pylon. hence the impossibility of describing them all), - On the post of the device according to the invention which may be subject to modifications without departing from the scope of the invention.

Claims (5)

RB) ENE) I CH'T IONS li Device for raising the pylons of pompas wind turbines, characterized in that it consists of a pole (11) of small size provided with two fixing systems. the first s: fixing system 12), located at the base of the post, allowing the post to be fixed to the top of the pylon, the second fixing system (13), located at the top of the post, allowing the fixing of a head wind turbine on the pole.  2) Device according to claim 1 characterized in that the post is a tube (14) of steel.  3) Device according to claim 1 characterized in that the post is a conical tube (23) of steel.  4í Device according to claim 1 characterized in that the post is a metal structure of small size and almost constant section.  5) Device according to claim 4 characterized in that the metal structure is of square base, consisting of four vertical angles (33) connected together by flat bars (347, the structure thus forming a trellis.  6) Device according to claim 1 characterized in that the post is a metal structure, compact, and whose decreasing section of the base at the upper end.  7) Device according to claim 6 characterized in that the metal structure is of square base, consisting of four angles (43) non-parallel whose overlapping ends are welded together; these four angles are connected together by flat bars (44), the structure thus forming a trellis.