ITLT20130007A1 - VERTICAL WIND TURBINE PLURIVELA WITH ALA TRONCA - Google Patents

Description

MULTI-VERTICAL AXIS WIND TURBINE WITH TRUNK WING

Brief outline of the essence of the invention.

Vertical axis wind turbine (illustrated with drawing tables 00,01,02,03,04) composed of coaxial helical sails, built with variable profile thin sheet metal inserts, combined coupling with glue and rivets. With the value of an element of street furniture and low environmental impact if installed in a historical context. With differential and sensitive response capacity to wind stress, obtained through a concave section with variable development, stabilized by shape and therefore without the aid of stiffening sections, with consequent lowering of the cut-in value, increase of the working capacity and pollution zero acoustic. Made in right-hand and left-hand version for Γ series installation with short system center distance. Made in different cuts for the production of different powers in Kw. Made in two, three and four versions, sails. Recalized without sectioning of the base and with truncated apex, as better illustrated in the following drawings.

State of the art of vertical axis wind turbines.

Currently the generation of electricity from wind sources takes place for large powers with generators with large propellers with horizontal axis, large plants aggregated in so-called wind farms of significant environmental impact, problems of noise pollution and require a very high economic commitment. For small powers, plants with mini-propellers always with a horizontal axis or alternatively generators with a vertical axis according to two fundamental models, the Darrieus and the Savonius, are used, with different detailed characterizations according to the different manufacturers. The Savonius generator is virtually a coupling of several half cylinders around an axis that intercepts the wind from various directions and drives an alternator that produces electric current. In recent years, some manufacturers have worked on an evolution of this generator by twisting a cylinder according to a helical development of 180 degrees from the base to the top. This torsion essentially responds to the need to intercept the wind from all directions of impact, its horizontal 'S' section solves this problem but virtually does not implement the working capacity of a traditional Savonius generator, as the application of the wind vector occurs for the time in which this coincides with the arc of a circle defined by the section half cylinder. That is, the impact wind flows horizontally over the section and is effective for the time it takes to exit, almost horizontally, at the point of impact. Moreover, this generator, while responding as mentioned to different wind directions, requires substantial thicknesses of sheet metal and horizontal stiffening structures, commonly made with arms, ribs or tie rods that constrain and stiffen the system with consistent weight increases and a consequent raising the wind speed necessary to start the generator, which electively directs its use in areas with consistent winds.

Real description of the invention.

The turbine for which a patent is requested, represented with Drawing Tables 00, 01,02,03,04, represents the evolution of this state of the art. The basic idea was to associate the mathematical benefits brought about by the use of the spiral and the auger with those of the sail, precisely the sail of pleasure boats, with its characteristics of ductility, flexibility, ability to "foil", such as we say in marine jargon, the excesses of the gusts of wind. The hybridization of the propeller with the sail, (a proposition that in the first statement may frankly appear problematic), was first simulated with a 3D modeling, then refined with scale modeling in a workshop to verify the plausibility of the project hypotheses , further fine-tuned in the construction of the first prototypes. The process of conception, design, preventive verification and field verification of the invention has led to a radical redefinition and optimization of the fluid-dynamic processes concerning this type of generators. It has become possible to realize a radically innovative or rather completely new invention, revolutionary in terms of logic, mathematical rigor, simplicity of construction, installation and operation, efficiency and effectiveness compared to everything conceived or produced up to now.

First purpose of the invention is adaptivity. In the design program, it had to be capable of identifying modular and extensible principles to the infinite wind characteristics of the sites in which it was to be installed. The physical principles are unique, the adaptive configurations are different, a bit like the leaves of different tree species, capable of reacting and developing the same work in sometimes opposite climatic conditions. And so once the general system has been identified, a mast with a cylindrical section on which to weld a double system of straps for anchoring the sails consisting of paraorìzzontal loops, just like in the sails of sailing ships, a different number of sails, two, three and four with different apical configuration and in different sizes to be a functional invention for every conceivable request in the field of the wind power generation sector.

Second purpose is the aptitude to fully exploit the available force, the wind, or the objective of making the flow of the wind vector active for as long as possible. We have noted above how in traditional generators it is effective for the time in which this force travels the distance of the horizontal section of the generator half-cylinder, whether Savonius or spiral-shaped with constant section. The goal was to direct the wind force along a vertical direction forcing it to work for the longest possible application time value, because this would have implemented the turbine's working capacity. By bringing the torsion of the sails to 360 degrees and giving them an external profile that is not concentric with the internal coupling profile to the anchoring strips, the result is a progressive screwing of the sail, wide in the lower section, where it receives the maximum impact. of the wind, and gradually tighter towards the apicalc part, with the result that the active wind instead of laminating towards the outside along the minimum horizontal section is trapped in the space between the neighboring sails and forced to rise along an increasingly narrow section , so that in addition to dilating its application time, increasing its speed for the Venturi law, it further implements the virtuosity of the system. The study of the models and prototypes in the wind tunnel has also produced the truncated apical configuration and the continuous apical configuration, suitable for responding to different wind characteristics of the planting sites, as well as the adaptability of the invention on the basis of the different number of sails as mentioned above.

Third purpose is absolute reliability: elements with proven durability coupled with techniques derived from aeronautics rather than mechanics. Hence the choice of aluminum alloys coupled with a riveting process, structural stiffening through the technique of doubling the sections instead of the installation of structural arms. All this has made it possible to arrive at an invention conceived with elements suitable for reacting with unusual sensitivity to low wind speeds but capable of responding with as much implicit intelligence to conditions of extreme mechanical stress in the face of particularly violent winds.

THE FOUND.

It consists of the following elements and the following stages of implementation.

1. Shaft in aluminum alloy or in steel with cylindrical section, of different heights for the different production needs to which the turbines will be called to respond. The section of said shaft is obviously proportionate to the mechanical exercise commitment, where appropriate the mechanical strength is increased by inserting another reinforcement shaft inside it whose external section coincides with the internal dimensions of the main shaft. In this way there is the possibility of modulating structural capacities in terms of resistance and elasticity by acting inside the shaft and therefore leaving unchanged the external shape of the shaft itself on whose profile the strap system for anchoring the vents is mounted. of the sail.

2. Helical band of the same material as the shaft referred to in point 1 above, made with aluminum or steel section of suitable size (for example 10x60 mm on the turbine with 3000 shaft). This strip is curved according to a radius resulting from the application of the formula

Radius = shaft h x 3.14 / 2 a correction factor that takes into account the diameter of the support shaft.

This strip is subsequently subjected to 360 ° torsion developed on the total height of the shaft and coupled by specific welding to the aforementioned shaft.

3. At this point we begin to infer the brackets, always in aluminum alloy or specific steel, by riveting them on the aforementioned strip and making sure that their edges are overlapped, giving them through this device a structural stiffening due to the doubling of section along the overlapping edges. The shape of the internal edge of the slits along the perimeter of coupling to the strip referred to in point 2 above is traced with the same geometric procedure, always specified in the same point.

The shape of the outer edge of the ribs (which will configure the external profile of the wing traced as already mentioned is identified by a different arc of a circle, offset from the one that determines the internal curve of the surface of the ferzo. This arc will be eccentric and of less development compared to the one that shapes the internal perimeter of coupling to the flap, so as to produce an envelope shape of the wing widened downwards, compressing the center of gravity of application of the wind vector to the ground, with considerable attenuation of the shear stress and of bending over the entire turbine system.

The virtual profile of the edges of the ribs in correspondence with the rib / rib overlap is oriented along lines converging towards the theoretical center of the arc of the circle with which the strip was determined in order to offer a unique virtual convergence line to the lines of force constituted from the coupling of the same ferzi.

The tracing of the profile of the ribs along the edges of the rib / rib overlap takes place with an increase in the edges, in order to have the possibility, during assembly, of following the natural continuity of the curvature of the ribs themselves, (variable according to the nature and thickness of the sheet itself).

4. At this point, the counter-strap for anchoring the splines starts working. It is traced in accordance with the strip described in the previous point 2 and placed in place at the time of the insertion of the loops on the said strip with a procedure which provides for a first fixing with bolts to stabilize the positioning of the loops, the subsequent welding of the same counter strap in parallel with the first strip, and the final fixation which involves the gradual removal of the positioning bolts and their replacement with rivets which ensure the definitive fixing of the brackets themselves.

This system of welding a double helical strip to the shaft, possibly already reinforced by the insertion of additional internal sections as described above, constitutes a substantial addition to the mechanical resistance capabilities of the cylindrical shaft; these fins helically welded along the perimeter of the shaft and whose primary function is to infer the ferzi take on a mechanical function of primary and decisive importance from the point of view of the capacity of resistance to bending and shear of the aforementioned cylindrical shaft actually performing a double function, supporting and blocking the lowering of the ferzi and doubling the mechanical performances of the shaft without increasing the weight and therefore without decreasing the reactivity of the turbine to the wind vector.

5. At this point, the apical stiffening gussets are placed in correspondence with the top barriers, in order to give maximum rigidity to the sections of the sails affected by the maximum acceleration flow of the captured wind with an appropriate structural redundancy device of irrelevant weight but extremely effective.

6. The front and rear stiffening gussets of different extension are also mounted on the basal lining, in correspondence with the attachment of the sail to the protective cap of the wind sail support case.

7. Then we proceed to the regularization of the external profile of the wings by mounting a cylindrical tubular extruded section in aluminum or steel to give rigidity along this edge and implement the effectiveness of the rising air flow along the free sections between neighboring wings.

8. The operation is concluded by riveting the stabilization gussets of the edge-covering tube in correspondence with the coupling of the clips, made of suitably shaped sheet metal, for the final stabilization of the entire system.

The turbine object of this report is made with two, three or four blades, and as mentioned in different cuts, depending on the electrical energy riser to be produced, in two different assemblies, right-hand and left-hand in order to install batteries of generators in particular conditions. where it should be necessary to install several propellers in series in confined spaces, for example the solar roof of a condominium where it is not possible to install them at a safe distance to ensure an undisturbed wind cone, these can be mounted at a very short distance along the line orthogonal to the direction of maximum wind found on the site. In this way, i.e. alternating right-handed blade with left-hand blade, the rejection wind of one is taken over by the next blade, and that is, it becomes effective for the neighboring blades, up to even triggering a mechanism of reciprocal sequential excitation, for which it starts any one of the series, this automatically rotates the neighboring propellers and these in turn the successive blades, activating a sort of alternating synchronization of rotation of the entire battery of generators. The distance must be calculated according to the prevailing wind conditions at the plant site.

Claims (6)

VERTICAL AXIS WIND TURBINE MULTIVELA WITH CONTINUOUS WING CLAIMS Vertical axis wind turbine (VAWT) as per one of the preceding claims characterized by the fact that: the wings (4) seen in section assume a spiral and progressive curve which, associated with the helical torsion proportional to the shaft (1), creates a rising channel delimited by the wings themselves that screw around the tree with a progressive narrowing that starts from the base where it is wider and reaches the top where it is narrowest. Claims. 1. Vertical axis wind turbine (VAWT) composed of: cylindrical shaft (l), strip (3) subjected to torsion, trapezoidal ribs {5) which together form two to four wings, counter-strip for the final anchoring of the ribs, stiffening gussets and also characterized by: a shaft (l) reinforced with a counter shaft (2} internal and welded to the outside a band! la (3) characterized by a helical torsion greater than 270 degrees developed uniformly along the entire height of the the wing (4) also the latter is composed of aligned ribs (5) characterized by a cross-rib overlap converging on a single center to be configured as a structural arm and which align to form two profiles, internal and external which determine the shape of the turbine and its wings which are sealed to the shaft with the riveted and welded counterband application along the entire development of the wing. 2. Vertical axis wind turbine (VAWT) as per claim 1 characterized by! fact that: its cylindrical shaft (l) has a countershaft (2) inserted inside to reinforce the lower part and strips (3) helically welded along the outer perimeter of the shaft for the entire length of the wing acting as structural reinforcement for the upper part and hooking waiting for the fasteners (5) making up the wing itself (4). 3. Vertical axis wind turbine (VAWT) as per one of the preceding claims characterized by the fact that: the strip (3} made of the same material as the shaft is curved according to an arc of a circle deriving from the radius resulting from the following formula: r = {wing height x (ir ÷ 2)) shaft diameter furthermore the strip is characterized by a torsion greater than 270 degrees developed along the total height of the wing and welded to the mast while waiting for the hooking of the clips (5) that make up the wing itself (4). 4. Vertical axis wind turbine (VAWT) as per one of the preceding claims characterized by: the trapezoidal ferzt (5) that make up the wing are placed side by side and assembled by riveting on overlapping edges converging on a single center to be configured as arms structural reinforcement and also characterized by an internal profile that follows the curvature of the waiting strip and an unequal and eccentric external profile to lower the center of gravity of the wing by widening the lower part to improve the response to wind and stress. 5. Vertical axis wind turbine (VAWT) as per one of the preceding claims characterized by the fact that: the counter-strip drawn in accordance with the strip is bolted, welded and finally riveted to allow a solid final anchoring of the wings (4) to the tree (l}. 6. Vertical axis wind turbine (VAWT) as per one of the preceding claims is characterized by the fact that: it comprises frontal (6) and rear (7) handkerchiefs of different extension on the basal shaft which stiffen it in correspondence with the attachment of the wing (4) to the protective cap of the turbine case