ES2448317B1 - AEROGENERATOR - Google Patents

Abstract

The present invention proposes a vertical type wind turbine. The present invention has as its main advantage over conventional wind turbines, which is capable of harnessing the energy of turbulent currents in addition to laminators. The wind turbine comprises a mobile turbine (1), a fixed outer part (12), aerodynamic vertical profiles (4) and a rotation axis (8). The mobile turbine (1) is hollow and comprises: an upper cover (9), a lower cover (10); entrances (13) and concave profiles (11), such that the mobile turbine is able to rotate angularly by means of the individual or combined action of: i) the thrust made by the incident laminar currents on the concave profiles (11); ii) the thrust made by at least one vortex created by the incident turbulent currents at an interior point of the mobile turbine (1).

Description

5 Object of the invention.

The present invention proposes a wind turbine of the "vertical axis" type, which by means of its connection to a mechanical to electrical energy conversion system is capable of generating electrical energy.

The present invention has as its main advantage over conventional wind turbines, which is capable of harnessing the energy of turbulent currents in addition to laminators. That is, turbulent currents improve the performance of the wind turbine of the present invention instead of decreasing the performance as is the case with wind turbines of the prior art.

The invention is part of the Energy-related technologies sector and, more specifically, in the field of wind energy transformation technologies in any other type of energy, mainly electrical energy.

Background of the invention

Vertical type wind turbines are known in the state of the art as disclosed in patent application US-A1-2007 / 0274830 with the title "Eolic Energy Transformation Tower". This patent application discloses a mobile turbine comprising a set of concave blades joined together by a vertical axis that connects to a mechanical energy transformation system in

25 electrical energy.

Also known in the prior art are vertical type wind turbines such as the one disclosed in US-A-4486143 "Turbine-type Wind Machine" by McVey, which also discloses a system of panels that orient the incident air flow to the turbine.

State-of-the-art documents take advantage of laminar currents but are negatively affected by turlish currents.

Therefore, it would be desirable to find a wind turbine that would take advantage of both currents, laminar and turbulent, to generate mechanical movement and. therefore, electrical energy.

In the context of the present invention, laminar currents are those currents generated by a laminar flow of air, and turbulent currents are those generated by a turbulent flow of air.

Description of the invention

The present invention discloses a wind turbine capable of taking advantage of the laminar and turbulent currents generated by an incident air flow over the wind turbine.

45 In order to take advantage of the thrust of the turl: lulent currents, the wind turbine of the present invention has a mobile rifle with a design that allows the creation of vortices inside, increasing the thrust on the inner surface of the turbine, thus obtaining Higher wind power efficiency available.

Therefore, in the essential embodiment of the invention associated with the mobile turbine, the mobile turbine is hollow and comprises at least one air flow inlet inside the mobile turbine turbine, angled aerodynamic profiles in the preferred direction of movement (time or anti-clock) of the turbine: mobile line and a configuration such that the mobile turbine is able to rotate angularly by

55 the individual or combined action of: i) the thrust carried out by incidents of laminar incidents on the profiles; ii) the thrust carried out by at least one vortex created by turl currents: violent incidents at an interior point of the turl: mobile line.

In the preferred embodiment of the invention associated with the wind turbine, the wind turbine of the present invention comprises: i) a mobile turbine; ii) a fixed outer part comprising a lower part and an upper part and aerodynamic vertical profiles arranged between the lower part and the upper part, where the aerodynamic profiles are angled in the direction preferred to the movement (hourly or anti-clockwise) of the mobile turbine; and, iii) a rotation axis that connects the mobile turbine with the fixed outer part and that allows an angular rotation of the turbine: mobile line, where the axis of rotation is connectable with a system of conversion of mechanical energy to electrical energy . The wind turbine is characterized in that the turbine: mobile line is hollow and comprises: i) an upper deck; ii) a lower cover; iii) some entries arranged between the top cover and the cover

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lower; Y. iv) concave profiles arranged between the upper cover and the lower cover connected to each other by means of the entrances; such that the mobile turbine is arranged inside the fixed outer part, which captures and channels the incident air flow, which generates incident laminar currents and incidental turbulent currents, through the aerodynamic vertical profiles in such a way that the incident laminar currents and the incidental turbulent currents reach inside the mobile turbine after crossing the entrances and, where the mobile turbine is able to rotate angularly through the individual or combined action of: i) the thrust made by said laminar currents incidents on said concave profiles; and, ii) the thrust made by at least one vortex created by the turbulent currents incident at an interior point of the mobile turbine.

The mobile turbine of the present invention takes advantage of the thrust of all the vortices that are created at any interior point of the mobile turbine, the mass point of the mobile turbine being the optimum point (which can coincide with the mass center of the wind turbine) . That is, the vortex created in the center of mass of the mobile turbine creates a maximum thrust on the mobile turbine. That is why, in an embodiment that contains any of the above, the inner point of the mobile turbine is the center of mass of the mobile turbine.

On the other hand, the axis of rotation connects the mobile turbine with the fixed outer part through the interior of the mobile turbine or without crossing the interior of the mobile turbine. In the preferred embodiment of the invention, the axis of rotation does not pass through the mobile turbine because thus the creation of the vortex in the center of mass of the mobile turbine is favored when the position of the center of mass of the mobile turbine and the axis coincide.

In the preferred embodiment of the invention, the wind turbine additionally comprises a system for opening and closing the aerodynamic vertical profiles such that the speed and direction of the incident laminar currents and the incident turbulent currents towards the interior of the mobile turbine are controlled by the opening of the aerodynamic vertical profiles.

The present invention has the following innovative advantages:

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Higher performance. The wind turbine of the present invention allows greater use of wind energy generating vortices in the hollow interior turbine due to its innovative design. This quality allows the wind turbine of the present invention obtain higher yields than wind turbines current for the same incident winds.

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Large operating margin. The wind turbine of the present invention, due to its design, obtains high performance, whether in high as in low wind speeds, covering with a single machine, a broad spectrum of designs, both horizontal and vertical axis.

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High efficiency for turbulent winds at any speed (high or low) speed. The wind turbine of the present invention obtains high efficiency in this type of regime due to its design and the vortices that are created inside. Turbulence is a panametro who always plays in against the use of wind energy, that is, as it increases, the effectiveness and performance of the machines. Due to the wind turbine design of the present invention, which is based on the creation of turbulent flows inside, this type of air flow (turbulent) incident, never decreases the efficiency or performance of the machine, but favors it.

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Integration arc itectón ica. Due to the design of the wind turbine of the present invention, the non-existence of moving parts external and taking advantage of turbulent winds, this machine is a perfect solution for your installation in buildings of all kinds, both on facades and on roofs.

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They can be grouped. The wind turbine of the present invention does not need to keep a margin of great distances between wind turbines, as with current wind turbines, because it takes advantage of turbulent regimes and the low deceleration suffered by the wind when leaving the wind turbine, both qualities present in the air currents expelled by wind turbines.

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Absence of external moving parts The wind turbine of the present invention has no external mobile part susceptible to cause some danger, as in conventional wind turbines and their blades (blades).

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No lifting necessary for installation. The wind turbine of the present invention has no external moving parts that can generate danger to people (as is the case with current shovels) and take advantage of low and turbulent winds, so It can be located a short distance from the ground while maintaining high performance.

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Less noise in operation (reduction of noise pollution). The wind turbine of the present invention has a design that minimizes noise pollution and does not create the characteristic noise of wind turbines with horizontal axis blades, due to the shielding suffered by the sound caused in the inner moving part, by the external fixed part.

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Detachable (low volume and easy transport). Due to its constructive simplicity, the wind turbine of the present invention has a design Easily removable which reduces its volume, making it easy to transport.

•

No need for guidance mechanism. The wind turbine of the present invention has a design with a circular symmetry "that allows it to take advantage of wind energy, regardless of wind direction, without the need for any orientation mechanism, guaranteeing maximum use of available wind energy at all times. .

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Brief description of the figures.

In order to complement the description of the invention and its characteristics, it is accompanied as integral part of said description the following figures.

Figure 1 represents an embodiment of the wind turbine of the present invention. Figure 2 shows a mobile turbine according to an exemplary embodiment of the present invention. Figure 3 shows a detail of the outer part channeling the air flow according to an example of embodiment of the present invention. Figure 4 shows the section on horizontal plane at height h / 2 of the wind turbine according to an example of embodiment of the present invention. Figure 5 shows a detail of the opening and closing system of the vertical profiles of the piece external system Figure 6 shows the results obtained in wind tunnel for the turbine rotation regime indoor depending on the incident air speed.

Description of an embodiment of the invention

An exemplary embodiment of the wind turbine of the present invention is shown in Figure 1. Saying wind turbine comprises a fixed outer part 12 shown in Figure 3 and a mobile turbine 1 interior shown in Figure 2. For the same example of embodiment of Figure 1, Figure 4 shows the section on horizontal plane at height hl2 of the wind turbine, where they are also shown aerodynamic profiles 4 and a rotation axis 8. The mobile turbine shown in Figure 2 has Five-pointed star shape, where each tip has a straight shape towards the entrance of the flow of air and convex if you look in the opposite direction to the airflow inlet in a plan view of the interior mobile turbine 1. Consequently, from an elevation view, each tip has a shape square or rectangular that forms a window for the entrance of the air flow into the interior of the interior 1 and concave mobile turbine if viewed in the direction of the air flow inlet into the indoor mobile turbine 1.

The fixed outer part 12 shown in Figure 3 is responsible for capturing and channeling the currents of incident flow to the interior mobile turbine 1 through the inputs 14 leaving the profiles together aerodynamic verticals 4. This part has two circular pieces, one lower 3 and one upper 2, and vertical aerodynamic profiles 4, represented in one of its aerodynamic embodiments.

the aerodynamic vertical profiles 4 allow us to channel the interior of the wind turbine, through the spaces 14 that remain between these and the upper 2 and lower 3 decks, laminar currents and turbulent incident currents. The positioning of the aerodynamic vertical profiles 4, angled all in the same direction, and aerodynamics, make the incident air flow, regardless of their incidence address, once they pass through them, enter inside the wind turbine with adequate rotation (clockwise in the embodiment shown in figure 4) that, In the next phase of the operation of this wind turbine, it will favor the movement of the turbine indoor mobile 1.

As seen in Figure 5, the aerodynamic vertical profiles 4 can be fixed or have a system that allows its gradual closing and opening (pitch), thus ensuring control over the air flow that is channeled to the inner mobile turbine 1. Through this mechanism we can ensure the operation in a stable regime of the electric generator (alternator) without getting into generation or losses, since we can maintain a constant air intake regime by closing the profiles if the wind increases, or opening them if it decreases. A possible opening system can consist of two electric hydraulic motors (not shown) for each aerodynamic vertical profile 4, one located at the top and another at the bottom, and rails (not shown) on the discs upper and lower, through which the inner ends 16 of the profiles slide when the closing and opening motors. On the other hand, the external ends 15 remain fixed and operate at Spinning axes mode for aerodynamic vertical profiles 4. The power supply of this

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Opening system would be provided by the wind turbine of the present invention and its control would be programmed and installed in the wind turbine controller.

the inner mobile turbine 1, shown in detail in Figure 2, is composed of a cover

5 upper 9 and lower 10, concave vertical profiles 11, a vertical axis 8 and inlets 13 so that the fluid can access its interior. Inside the turbine 1, and preferably in its center of mass, it is where the vortices appear, which are produced by the rotating circulation that already has the flow (due to the action of the external part Figure 3, as explained more above) and by the design of this internal part: hollow, with vertical flat inlets 13, curved interior surfaces 11 in the direction of rotation of the flow and lower covers 10 and upper 9 that allow to confine the flow within the mobile turbine.

the concave interior curvature (seen from the flow of air entering the part) of the vertical surfaces 11 of the interior mobile turbine 1 is what makes it possible to take advantage of the pressure exerted on them

15 the fluid that accesses the interior through the inlets 13 (since its power coefficient is greater than that produced by the flow when it affects the convex outer face of the same piece), as well as the extra thrust produced by the vortices, transfonnarlo in energy of mechanical movement. the mobile turbine 1 is a moving part that rotates clockwise (as already explained since the aerodynamic response to the incidence of the fluid is greater for concave surfaces than for convex, which causes the final torque to be positive in this direction) around a vertical axis 8 integral with the mobile turbine 1 passing through its center, which may or may not cross the intervening mobile turbine 1.

The axis 8, through its lower part, will be responsible for transmitting the mechanical energy by means of a torque or torque (proportional to the incident wind speed) to the phase of transfonation in

25 electric energy, located inside the cylindrical cavity 5, consisting of a multiplier (if the characteristics of the alterator requires it), alternator (the technology of the alterator: pennanent, polar, multipolar magnets, etc.), will depend on the specific dimensions of the machine and the specific generation needs), controller card and other necessary elements (not shown).

The turbine is anchored to any surface by means of anchoring utensils 7, located in the lower disk 6, integral with the entire turbine (see Figure 1).

Through numerical simulations with CFD (Computational Fluid Dynamics) techniques, it was possible

35 check that the creation of vortices inside the turbine improves the thrust on it. By simulation and for a velocity field with an initial incident speed of 6 ms and direction () Or in a cross-sectional plane at mid-height of the wind turbine of the present invention (same section as Figure 4), it has been observed that the vortices have the property of generating highly turbulent currents of great magnitude in speed of up to 13,125 mis, starting from an incident speed of 6 mis, which favor the thrust in favor of the movement of the inner mobile turbine. The efficiency in the high rotation regime without aerodynamic decay is also shown in Figure 6, where up to 13m / s wind speed is reached in the wind turbine. Figure 6 shows the mean quadratic regression performed on the measurements of six experimental series with sixteen measuring points each, also included in the figure and symbolized

45 by means of different typology of signs (cross, square without filling, square with filling, point, blade and horizontal line) in working regimes (rotation frequency) from 1 to 7.8 Hz for incident wind speed from 1 to 13 mis . Achieving such a high speed (7.8 Hz at 13 m, with a homemade prototype) allows for a functioning in which the use of mechanical turn multipliers is not necessary. That is to say, this rotation regime is suitable for the conversion of wind energy into electrical energy by means of the direct use of the generators currently available in the market, either in direct or alternating current, either in small machines (400W -10000 W) or large (10000 W -100000000 W). The data contained in Figure 6 show a highly linear trend of increasing the frequency of rotation as a function of the incident wind speed. Up to the speed limit of the wind tunnel available for prototype testing, 13 m of incident wind speed, the wind turbine prototype does not

55 enters aerodynamic loss (decay of the rotation regime). In no case, it can be inferred that the wind turbine of the present invention cannot reach a rotation speed greater than 7.8 Hz without entering losses.

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Claims (4)

   1.-Wind turbine comprising: • a mobile turbine (1); 5 a fixed outer part (12) comprising a lower part (3) and an upper part (2) and aerodynamic vertical profiles (4) arranged between the lower part (3) and the upper part (2), where the perilles aerodynamics are angled in the direction preferred to the movement of the mobile turbine (1); a friction shaft (8) that connects the mobile turbine (1) with the fixed outer part (12) and that hangs 10 an angular rotation of the mobile turbine (1 l, where the axis of rotation (8) is connectable with a system of conversion of mechanical energy to electrical energy; characterized in that the mobile turbine (1) is hollow and comprises: • a top cover (9); • a lower cover (10); 15 • inlets (13) arranged between the upper cover (9) and the lower cover (10); • concave profiles (11) arranged between the upper cover (9) and the lower cover (10) connected to each other through the inputs (13); such that the mobile turbine is arranged inside the fixed outer part (12), which captures and channels an incident air flow, which generates incident laminar currents and currents 20 turbulent incidents by means of the aerodynamic vertical profiles (4), in such a way that the incident laminar currents and the incidental turbulent currents reach the interior of the mobile turbine after crossing the entrances (13) and, where the mobile turbine is capable of rotating angularly by means of the individual or combined action of: i) the thrust made by said incident laminar currents on said concave profiles (11); and, ii) the thrust made by at least one vortex created by the currents 25 turbulent incidents at an interior point of the mobile turbine (1). 2. Wind turbine according to any one of the preceding claims, characterized in that the rotation axis (8) connects the mobile turbine (1) with the fixed outer part (12) crossing the interior of the mobile turbine or without crossing the inside said mobile turbine (1). 3. Wind turbine, according to any one of the preceding claims, characterized in that said wind turbine additionally comprises a system for opening and closing the aerodynamic vertical profiles (4) such that the speed and direction of the incident laminar currents and the 35 turbulent currents incident towards the interior of the mobile turbine (1) are controlled by the opening of said aerodynamic vertical profiles (4).