IT202300000666A1 - WIND AND/OR PHOTOVOLTAIC ELECTRIC GENERATOR WITH A VERTICAL AXIS TURBINE WITH BLADES THAT INCLINE WITH RESPECT TO THE DIRECTION OF THE WIND AND A SOLAR TRACKER PLACED ABOVE IT, ON THE SAME AXIS OF ROTATION - Google Patents

Description

Title:

Wind and/or photovoltaic electric generator with a vertical axis turbine with blades that tilt with respect to the direction of the wind and a solar tracker placed above it, on the same rotation axis

Summary

Wind and/or photovoltaic electric generator consisting of a vertical-axis turbine above which there is a photovoltaic solar tracker having the same axis of rotation. The wind turbine is characterised by flat or slightly concave blades, of rectangular shape, each of which has an axis of rotation corresponding to a vertical edge, with protruding hubs inserted in the hinges of the upper and lower rotor arms, and an idler wheel at the upper vertex of the other edge, parallel to the first; this idler wheel moves in a hollow guide, placed at the top in a plane normal to the turbine axis, which is closed in a ring and has a circular shape of radius R for 180 ?, after which it follows a depressed curve with a decreasing radius for 90 ? and then with an increasing radius up to R for the remaining 90 ?; this guide for wheels is connected to a rudder that rotates around the fixed axis, independently of the turbine, and aligns itself with the direction of the wind, so that the blades are arranged radially when they are downwind, due to the effect of the wheel that translates in the circular section of the guide and therefore transmit a driving torque to the rotor, due to the wind pressure. Instead, when the blades travel against the wind they automatically tilt in the direction of the wind, due to the effect of the wheel that travels along the depressed curve section of the guide. Therefore, they do not transmit the torque due to the wind pressure to the rotor, but only that due to the friction of the air on the blades.

State of the art

The technical field of the following invention is that of alternative energy sources, wind and photovoltaic. Normally these two solutions include photovoltaic panels and turbines that are functionally distinct from each other and also occupy different spaces. In this invention a unique solution is proposed that includes a vertical-axis turbine with tilting blades and a series of photovoltaic panels mounted on a solar tracker placed above the turbine and mounted on the same fixed axis. This solution is very versatile and can be used in civil and industrial installations. The wind-photovoltaic combination also guarantees good continuity in the energy supply. Furthermore, the wind turbine can develop large powers thanks to the tilting flat blades. In this regard, it is noted that in horizontal-axis turbines the blades rotate in a plane normal to the direction of the wind, due to the effect of a tail rudder. On the other hand, vertical-axis turbines generally do not have a rudder, and during rotation some blades are downwind, while others are against the wind. Therefore, to obtain rotation it is necessary to use a rudder. It is necessary to create an imbalance between the driving torque acting on the blades downwind and the braking torque acting on the blades against the wind. Furthermore, the force acting on each blade changes continuously with rotation, because both the surface area invested and the angle of incidence of the wind on it change. To obtain more torque and also more power, it is not enough to increase the surface area of the blades but it is also necessary to act on their spatial shape. In particular, it is necessary to tilt the surface like in a propeller, so as to always have, even partially, a surface normal to the direction of the wind and this involves an increase in the radius. The increase in the radial dimensions of these turbines has limited their application in civil activities such as a residential building. In this type of activity, in fact, it would be very useful to have compact and space-saving vertical-axis turbines capable of supplying up to 100 kW. To have a turbine of this type, flat blades should be used that maximize the force according to the rough formula F = A x p x C , where A is the surface of the blades, p is the wind pressure and C is a shape coefficient. Unfortunately, the wind turbine with flat blades arranged in a star of planes does not work well, because the driving torque downwind and the braking torque against the wind are not very different from each other, even if three 120 ? blades are used.

This new invention proposes the use of flat blades that automatically tilt during rotation with respect to axes parallel to that of the turbine, in order to reduce the braking torque against the wind. The blades tilt thanks to idle wheels, i.e. cams, which rotate and translate in a hollow guide closed in a ring around the axis of the turbine. This wheel guide is then connected to a rudder, placed at the top, which orients it in the right direction with respect to the direction of the wind. The shape of the wheel guide is such as to maximize the force of the wind on the blade when it turns downwind, while when it turns against the wind the blades tilt to reduce the force against the wind to the minimum possible.

The closest state of the art is given by the Chinese patent CN104214042A. This patent Fig.7 provides for two types of blades. The rotor blades 20), which are fixed and have an airfoil profile. And the stator blades 4), which are connected to a rudder that tilts them in such a way as to divert the wind in a way that is favorable to the rotation of the rotor blades. In this Chinese patent the rotor blades are fixed with respect to the rotor and do not tilt with respect to the axis of the turbine. Instead, the stator blades tilt by means of a rudder and divert the wind in the way that is most convenient for the rotor blades. The idea of divert the flow on the rotor blades is feasible only if a large number of blades are installed on the stator, in order to effectively channel the flow towards the rotor. In fact, if the stator blades are too far apart, the wind passes into the free space between the stator and rotor blades. That is, it follows its natural direction without being deviated, so the wind reaches the rotor even in the unfavorable direction. On the other hand, if the number of stator blades is increased to effectively deviate the wind flow, the air resistance on the blades increases and, at low speeds, little wind reaches the rotor. On the other hand, this patent does not include any solar tracker on the same fixed axis of the turbine and related photovoltaic panels.

Compared to patent CN104214042A, this new patent has two innovative aspects: the solar tracker with relative photovoltaic panels above the turbine and on the same fixed axis and the rotor blades that tilt during the rotation of the turbine. The blades assume a radial position when they travel downwind, with the idler wheel that travels along the circular guide section. Instead, when the blades travel against the wind, the idler wheel travels along the depressed curve and this causes the blades to tilt in the direction of the wind. In this patent, the rudder orients the hollow guide for idler wheels and these, during translation in the guide, tilt the blades. This simple and automatic way of functioning maximizes the driving torque downwind and minimizes the braking torque against the wind. In conclusion, the two patents are conceptually and profoundly different even if they both use a rudder.

Description

The wind and/or photovoltaic electric generator is made up (Fig.1 table 1) of an open support frame 1), similar to a cylindrical squirrel cage, which at the top has a hole with a bearing 2) inside which a bushing 3) is inserted, equipped with an internal bearing through which passes a fixed axis 4) which has its base 5) connected to the frame 1). The bushing 3) can rotate both with respect to the frame 1) and to the fixed axis 4). The upper part of the bushing 3) is connected to a rudder 6). Instead, the lower part of the bushing 3) is connected to a disk 7) which rotates with it. On the external edge of this disk 7) there are bearing spheres 8) which rest on a fixed circular crown 9) which is part of the frame 1). These ball supports 8) stabilize the disk 7) during the rotation produced by the rudder 6) around the fixed axis 4) due to the wind. Under the disk 7) there is a hollow guide 10), closed in a ring around the fixed axis 4). The turbine rotor 11) is made with a hollow tube 12) equipped with bearings, which rotates around the fixed axis 4). At the beginning and end of the hollow shaft 12) there are a series of arms 13) in the planes normal to the axis of the hollow shaft itself. At the ends of these arms there are the hinges 14). The blades 15) (Fig.1 and Fig.2 table 2) have a rotation axis 16) parallel to the axis of the turbine and its hubs are inserted into the hinges of the rotor arms. On the other side of the blades, in correspondence with the vertices, there are idle wheels 17) which translate in the hollow guide by rollers. The blades are made (Fig.1 and Fig.2) of a rigid material frame to which a windproof fabric 18) is attached and stretched. The hollow guide for the wheels (Fig.3 table 2) has the shape of a circumference of radius R for 180 ?, after which it follows a curve with a decreasing and then increasing radius up to the value R. The radius R is equal to the distance between the wheel on the circular section and the axis of the blade (fig. 2). Alternatively (Fig. 4 table 2) a second hollow guide for the wheels can also be mounted at the lower end of the hollow shaft, above another disk 19) which has a central hole. The lower disk 19) is connected to the upper one 7) by means of three or more vertical rods 20). This disk 19) (Fig.1 and Fig.4 ; Fig.5) is also equipped with load-bearing spheres that translate over a fixed crown 21) integral with the frame 1). In the lower area of the hollow shaft of the turbine (Fig.1 and Fig.6) there is a flange 22) to which a toothed wheel 23) is connected which, via the pinion 24), activates the generator 25). Near each hinge 14) of the arms 13) there is a limit switch 26) (Fig.6 and Fig.7) which, when the blade is downwind, allows the force to be transmitted from the blade to the turbine rotor. Between the hubs 16 (Fig. 1 and Fig. 8) of the blades 15) and the hinges 14) of the rotor arms there are torsion springs 27) which straighten the blades when they pass from the upwind area to the downwind area (Fig. 8). The turbine rotor Fig. 9) can be made with upper, central and lower arms with the blades arranged on two planes. The blades of the two planes are connected to each other through the sleeves 28). In the area of the fixed axis 4) above the rudder is fixed a flange 29), an axial bearing 30), a second flange 31) which rotates with respect to the fixed axis, a frame 32) integral with the flange 31) which carries the photovoltaic panels 33). To operate the solar tracker, a toothed crown 34) integral with the flange 31) and a pinion 35) with motor 36) integral with the flange 29) are also provided. To increase the stability of the solar tracker, vertical rods 37) are provided at the ends of which are placed bearing spheres 38) which unload the weight of the panels onto a crown 39) integral with the frame 1) of the turbine. The device is equipped with a hook 40) connected to the fixed axis.

How it works

The solar tracker part works like all the other systems already in use. At dawn the panels face east and during the day the tracker rotates to always keep the panels perpendicular to the sun's rays. Instead, as regards the wind turbine, Fig. 10 shows a view of the turbine from above. If the wind is directed according to direction V, the rudder 6) rotates and positions itself behind the axis according to the direction of the wind, the hollow guide 10) for wheels 17) is positioned so that the circular section is to the left of the axis and the turbine rotates clockwise. In these conditions the blade that is on the circular section is downwind and provides a driving torque. Instead, the blades that are to the right of the axis rotate against the wind and tilt in the direction of the same wind, compatibly with the constraint of the wheel in the guide. These blades are distant from the end stops and the only braking force that they can transmit to the turbine is that due to friction on the blades and to the variation of the moment of inertia during the inclination of the blades.

Advantages

Compared to the state of the art, this new solution offers the following advantages:

- single generator that produces photovoltaic and/or wind electricity

- pre-assembled generator that can be simply placed on the roof of a building

- blades tiltable according to the direction of the wind;

- vertical axis blades with a large wind impact surface that make the turbine rotate even with little wind;

- with the same height and diameter, more powerful turbines can be built than non-tilting airfoil turbines;

- compared to horizontal-axis turbines, it is possible to build vertical-axis turbines with the same power but with a significantly reduced lateral footprint;

- the blades are flat or slightly concave and rectangular in shape, making them easy to make with both prefabricated panels and fabric sails on a support frame;

- simple mechanisms to make;

Claims (10)

Claims 1) Wind and/or photovoltaic electric generator characterised by a vertical-axis turbine, a solar tracker placed above it having the same axis of rotation, a fixed axis 4) on which a hollow shaft 12) rotates, equipped with radial rotor arms 13), each of which has a hinge 14) and a limit switch 26) at the end, these arms are placed in the planes normal to the turbine axis, in correspondence with the upper and lower ends of the hollow shaft, possibly also in an intermediate position; two or more flat or slightly concave blades 15), of rectangular shape, each of which has a rotation axis 16) in correspondence with a vertical edge, with the protruding hubs inserted in the hinges 14) of the upper and lower rotor arms, and an idle wheel 17) in the upper vertex of the other edge, parallel to the first; this idle wheel translates in a hollow guide 10), placed at the top in a plane normal to the turbine axis, which is closed in a ring and has a circular shape of radius R for 180?, after which it follows a depressed curve with a decreasing radius for 90? and then with an increasing radius up to R for the remaining 90?; this guide for wheels is connected to a rudder 6) which rotates around the fixed axis, independently of the turbine, and aligns itself with the direction of the wind, so that the blades are arranged radially when they are downwind, due to the effect of the wheel which translates in the circular section of the guide, instead they tilt when they travel against the wind, due to the effect of the wheel which travels along the depressed curve section of the guide; a flange 29) integral with the fixed axis placed at the highest point, above the rudder; an axial bearing 30) and a flange 31) which rotates around the axis 4); a frame 32) integral with the flange 31) which supports the photovoltaic panels 33); a toothed crown 34) integral with the flange 31); a pinion 35) and a motor 36) integral with the flange 29); 2) Wind and/or photovoltaic electric generator as in claim 1) characterised by a vertical axis turbine and a solar tracker placed above it, on the same rotation axis, flange 29) fixed to the axis 4), axial bearing 30), upper flange 31) and frame 32) carrying the photovoltaic panels; 3) Wind and/or photovoltaic electric generator as per the previous claims characterised by flat or slightly concave blades 15) of rectangular shape, each consisting of a frame to which a sail 18) in waterproof fabric is attached, such blades are equipped with a rotation axis 16) parallel to the rotor axis, an idle wheel 17) on the upper vertex of the other vertical side and a pin and/or another wheel on the lower vertex; 4) Wind and/or photovoltaic electric generator as per the previous claims characterised by a fixed vertical axis 4) supported by a frame 1) resting on the ground which in the upper part is equipped with a bushing 3), equipped with internal and external bearing, which rotates with respect to the internal fixed axis and the external frame; 5) Wind and/or photovoltaic electric generator as per the previous claims characterised by a rudder 6) with horizontal rod and vertical blade placed above the fixed frame and connected to the upper part of the bushing 3); 6) Wind and/or photovoltaic electric generator as per the previous claims characterised by a horizontal disk 7), equipped with bearing spheres 8) on the external circumference; this disk is fixed to the lower part of the bushing 3) and, underneath, carries a hollow roller guide 10); this guide is closed in a ring around the axis of the rotor and has the shape of a semicircle of radius R, while for the other 180 ? it has the shape of a depressed curve of decreasing radius and then increasing up to the radius R; 7) Wind and/or photovoltaic electric generator as per the previous claims characterised by radial rotor arms 13) with hinges 14) at their ends, positioned in planes normal to the axis of the turbine, in correspondence with the upper and lower ends and/or at an intermediate level; 8) Wind and/or photovoltaic electric generator as per the previous claims characterised by limit switches 26) on the hinges of the rotor arms which limit the rotation of the blades and torsion springs 27) on the rotation hubs of the blades which bring them back to a radial position with respect to the rotor axis; 9) Wind and/or photovoltaic electric generator as per the previous claims characterised by several rows of blades overlapped vertically and hinged to the corresponding arms of the upper, intermediate and lower levels of the turbine; these blades are connected to each other by means of a sleeve 28) which is screwed onto the pins of the blades in line with the wheels; 10) Wind and/or photovoltaic electric generator as per the previous claims characterised by a horizontal disk 19) with a central hole, equipped with bearing spheres 8) on the peripheral circumference which rest on the crown 21) fixed to the frame 1), this disk 19) is connected to the upper disk 7) via the vertical rods 20);