BRMU8903447Y1 - Constructive arrangement applied in installation of deflector panels for aerodynamic conversion of wind energy - Google Patents

Abstract

aerodynamic conversion of wind energy. modality: internal flow to the collector and concentrator panel - airflow collector and concentrator panel system, in association with an air turbine installed in a wind chamber, with activation by the internal air flow to the panel, which is formed by the circulation between soffit and soffit, when exposed to the wind current: see figure 3: fig. 3 shows on the collector and concentrator wind panel, the cross section 'of the typical module - section, including the following indicative signs of each descriptive detail: (1) cross section profile (title); (2) zone separation diaphragm; (3) angle of attack; (4) deflected air flow; (5) pressure distribution - soffit; (6) flow channel reducing plate; (7) pressure distribution - extrados; (8) maximum suction; (9) suction slit; (10) air outlet; (11) counterflow entry and retention window; (12) pressure zone; (13) maximum pressure; (14) pressure crack; (15) air inlet; (16) suction zone. the airflow collector and concentrator panel has its construction proposed by superimposed modules, firmly connected to each other from top to bottom of its construction. the modules must be designed to allow their division into two or more parts, in order to facilitate handling and transportation by trucks, trailers, wagons or other means. there will be an optimal relationship between the total area of the collector / concentrator panel and the size of the wind energy converting turbine, to be determined by experimentation and calculation, in order to take maximum conversion efficiency for each panel / turbine combination. due to the expected lateral aerodynamic load on the panel, it will be necessary to have an adequate stabilization that guarantees the stability and integrity of the construction, without however preventing its rotation in relation to a vertical axis, in order to allow the panel to align with the wind and maintain an ideal angle of attack. under certain construction limits, 2 (two) or more panels can be superimposed vertically, doubling or more the catchment area and the consequent conversion, while maintaining the optimal relationship between the area of the panel and the size of the turbine. however, assuming that for constructive and economic reasons it is concluded that a maximum standardized size of the air turbine is ideal, but that larger areas of the panel are also desired, then the wind chamber may be dimensioned to admit more than one turbine converter, in order to also optimize the panel area / total size of the turbines. internally in the pressure zone generated on the soffit of the panels, the air intake will be through windows with movable blades, for the purpose of differential counter flow retainers, allowing air to enter only if the local static pressure inside the pressure zone of the module, is less than the total pressure of the inlet flow. also in each module and according to its position at the height of the collector / concentrator panel, an area reduction plate will be installed in the pressure zone referring to the soffit, in order to progressively reduce the flow channel between modules from top to bottom, with effect of accelerate the internal flow and progressively reduce its static pressure. thus, with the combined action of counterflow retainers and flow channel reducers, the flows captured in each module will be incorporated and accelerated inside the collector / converter panel, adding their masses and gaining speed in the direction of the turbine. on the other hand, the air turbine converting the wind energy, will be exposed on one side to the dynamic pressure of the concentrated and accelerated flow of the pressure zone and on the other side, to the suction of the suction zone, converting the wind energy with the combined action of both the effects.

Description

CONSTRUCTIVE ARRANGEMENT APPLIED IN THE INSTALLATION OF DEFLECTOR PANELS FOR AERODYNAMIC CONVERSION OF WIND ENERGY

The present utility model deals with an unprecedented constructive arrangement applied in an installation of deflector panels, collectors and airflow concentrators, for aerodynamic conversion of wind energy, being applied in the use of energy in air currents, capturing, conducting and accelerating the current, to convert its energy into useful and controlled forms of use, through air turbines (s) installed in the section with the highest concentration of air flow, this turbine being driven by the internal current to the panel, which is form by the circulation between soffit and extrados, when the panel is exposed to the wind.

The collector panels can be defined as fixed or semi-fixed, and can be associated in connection with each other, in order to result in the capture of increased volumes and concentrations of the air flow, with the resulting increased use.

TECHNICAL FUNDAMENTALS

The large masses of air that move freely, even at moderate speeds, contain an appreciable amount of energy, but as they are dispersed, the energy is diffuse and its use on a large scale depends, however, on interference in large

2/9 areas in the airspace, which seems out of practical reach in capturing and converting simultaneously by pinwheels.

STATE OF THE TECHNIQUE state of the art document US 5484257 A, published on January 16, 1996, presents an installation (10) for the conversion of wind energy into mechanical energy. Such installation consists of an airfoil-shaped structure (12) that can be arranged horizontally or vertically. The airfoil (12) is composed of a front surface (16) and an extruder surface (14). Internally, it is divided by a wall (18), giving rise to a high pressure chamber (22) and a low pressure chamber (20). In the wall (18) there is an opening (24) where a turbine (28) is arranged, constituted by a rotor with blades (32) that can rotate around an axis (34). The airfoil (12) is orientable so that it can be positioned frontally to the wind (36), which enters through openings (38), creating a high pressure zone in the chamber (22). Due to the flow of wind on the external part of the surface (14), a low pressure region is created at this location that aspirates the air present in the chamber (20), reducing its pressure. As a result, there is a pressure difference between the two chambers (20 and 22), causing air to flow through the opening (24), driving the turbine (28). The shaft (34) can be coupled

3/9 to drive any device, whether electric, hydraulic or pneumatic.

INCONVENIENTS OF THE STATE OF THE TECHNIQUE

It turns out that the opening (38) located on the front surface (16) of the airfoil (12), responsible for capturing the air flow, is arranged exactly on the leading edge where the wind flow dissipates to the sides of the extrados and soffits of the airfoil (12), with the concave side of the lower pressure having the lowest pressure and the convex side of the soffit having the highest pressure, with the air flow passing externally through these surfaces presenting different speeds and pressures.

Another drawback noted in the installation (10) of the state-of-the-art airfoil structure (12), as taught by US 5484257 A, is the absence of effective and appropriate anchoring and anchoring elements to support higher energy speeds caused by aerodynamic load generated at great heights, directly reaching the region of the extrados and soffits of the structure when placed in a vertical position. This condition can cause tipping and irreparable damage to the installation, as well as danger to life for workers who may be close to the structure.

Another drawback of the structure (10) of the state of the art is related to the poor distribution of

4/9 pressure generated inside the high pressure chamber of the airfoil (12), as in this configuration, as soon as air is admitted into the high pressure chamber, a counter flow is created, capable of generating a whirlwind in the flow channel.

Another notable drawback in the airfoil (12) is the fact that it is made up of a monoblock structure (10), making it difficult to transport, assemble and install on land that is accessible only by urban roads with limited passages in terms of weight, height , depth and width.

OBJECTIVES AND PROPOSALS OF THE MODEL

One of the objectives of the present model in relation to the state of the art, is based on the proposal of an aerodynamic conversion panel for wind energy that optimizes the efficiency in harnessing the energy of the air currents flow, generating a useful and more efficient flow for energy conversion through a compact and proportionally low inertia turbine (s), in addition to making it feasible to assemble this type of installation in economic and logistical terms.

One of the proposals presented by the present model of Deflector Panels for Aerodynamic Conversion of Wind Energy, is to solve the speed control and direction of the incident air flow, whose intensity of energy to be converted is proportional to the square of the

5/9 speed produced with the concentration of air in the wind panel, which is not achieved with the simple exposure to the free, of devices to capture and convert the Wind Energy, as for example in the current Wind Turbines.

Another proposal of the present model is the use of fixed or semi-fixed anchoring elements of the interference panels, so that they can reach large areas of air space, to capture energy more efficiently through large amounts of air in motion, when compared to the teachings of the current technique. Therefore, the further the air currents are removed from the ground, the less they will be affected by their influence and, therefore, subject to higher energy velocities, which may improve the cost / benefit ratio to convert energy into useful and controlled forms of use.

According to the above, another proposal of the model is the use of a staging device in order to guarantee the stability and integrity of the structure, without preventing its rotation in relation to the vertical axis.

Other features and advantages of this model will be described below with the help of the attached figures.

DESCRIPTION OF THE FIGURES

Figure 1 - Side elevation of the collector panel and

6/9 concentrator;

Figure 2 - Typical cross section of the wind panel;

Figure 3 - Front and side elevation with indications of anchoring and flow in the wind chamber;

Figure 4 - Illustration of the system in lateral elevation, with indication of stanchions;

Figure 5 - Perspective of a schematic illustration of a typical module of the collector panel;

Figure 6 - Internal View - extrados, indicating modules and tapering of the flow channel;

Figure 7 - Internal view - soffit of the collector and concentrator panel, indicating entrance window with counterflow retention;

Figure 8 - Internal view - soffit of the collector and concentrator panel, indicating modules, tapering of the flow channel and concentrated and accelerated flow, and

Figure 9 - View of the cross section of the airfoil (12) of the state of the art taught by document US 5484257 A.

DETAILED DESCRIPTION OF THE MODEL

In accordance with the aforementioned figures, the new CONSTRUCTIVE ARRANGEMENT APPLIED TO THE INSTALLATION OF DEFLECTOR PANELS FOR AERODYNAMIC CONVERSION OF WIND ENERGY, object of protection of the

7/9 The present utility model patent application comprises an installation for transforming wind energy (wind energy) into a form of usable energy (mechanical and electrical). The operation of said installation is based on the separation between capture and conversion of air currents (7). The capture is carried out by a vertical panel (1) in the shape of an airfoil, where the deflected air stream (26) at an angle of attack (25) generated by the panel edge (1) is captured by the air inlet (23 ) formed by a pressure slit (22) located in the region of high pressure on its soffit (20).

air captured (23) by the pressure gap (22) enters an internal pressure zone (19) composed of a tapering plate (28) responsible for reducing the flow channel (11), generating a concentrated air flow and accelerated (12), passing through an intake window (23A) which is led to a wind chamber (3) located at its base, where the turbine (4) is located, where the generated air flow is responsible for drive the turbine (4), the flow being conducted through an exhaust window (18E) to the suction zone (14), where it is finally directed to another slot (17) that forms the air outlet (18) located in the extraction of the panel (1), in a low pressure region (15).

The high pressure (19) and low pressure zones

8/9 pressure (14) of the vertical panel (1) are divided and internally isolated by a diaphragm (24) separating the zones, preventing pressure interference between the zones.

In the high pressure zone (19) generated on the soffit, inlet windows (27) with movable blades (fins) responsible for retaining the counterflow of air are vertically arranged, allowing air to enter only if the local static pressure inside the zone pressure (19) is less than the total pressure of the inlet flow.

Thus, with the combined action of the entrance windows (27) responsible for retaining counterflow and the taper plate (28) responsible for forming a reduction in the flow channel (11), the flows captured in each module will be incorporated and accelerated inside the panel (1), adding its masses and gaining speed in the direction of the turbine.

On the other hand, the turbine (4) will be exposed on one side to the dynamic pressure of the concentrated and accelerated flow of the pressure zone and on the other side, to the suction of the suction zone, converting the wind energy with the combined action of both effects.

The actual installation of this panel (1) is carried out in superimposed modular parts in order to facilitate handling and transportation by trucks, trailers,

9/9 wagons or other means, which are seated above an anchoring base (6) disposed on the ground (8). Above the anchoring base (6), fixed or mobile anchors (5) are installed, responsible for supporting and moving the panel (1).

On the anchors (5) the first module that forms the wind chamber (3) is mounted, which centrally receives the assembly of the turbine (4). Above this module (3) the profile modules of the cross section (13) of the panel (1) are assembled and fixed in the shape of an airfoil. Once the panel is formed, in the upper portion of the regions of the soffit and the extrarse, stair rails (30) where the cables or stair bars (29) are attached, responsible for ensuring the stability and integrity of the structure, without prevent its rotation in relation to the vertical axis.

In a constructive alternative, the entire length of the respective sides on the soffit and soffit of the wind panel (1) may have several slits (17 and 22), taking advantage of the entire interference and capture capacity.

Claims (2)

CLAIM 1) CONSTRUCTIVE ARRANGEMENT APPLIED TO INSTALLING DEFLECTOR PANELS FOR AERODYNAMIC CONVERSION OF WIND ENERGY, comprising a panel (1) in the shape of an airfoil characterized by being made up of overlapping modular parts, seated above an anchoring base (6) arranged on the ground (8), equipped with fixed or mobile anchors (5) on which the first module of the wind chamber (3) is placed, centrally comprising the turbine (4), where the profile modules of the cross section (13) are superimposed in airfoil shape that make up the panel (1); the upper portion of the soffit and panel extraction (1) have rails (30) provided with cables or rails (29); in the soffit portion, at least one pressure slot (22) is provided for the air inlet and in the extractor portion, at least one exhaust slot (17) for the air outlet is arranged; the inner areas of the high pressure (19) and low pressure (14) panel (1) are divided by a diaphragm (24) arranged between the intake window (23A) and the exhaust window (18E) of the wind (3), the high pressure zone (19) being provided with a tapering plate (28) and counter-flow windows (27) equipped with vertically arranged mobile blades. 2) CONSTRUCTIVE ARRANGEMENT APPLIED TO AN INSTALLATION OF 2/2 DEFLECTOR PANELS FOR AERODYNAMIC CONVERSION OF ENERGY WIND POWER, according to claim 1 and in a constructive alternative, said panel (1) is characterized P ^or constitute more than one gap (17 and 22) in the extension of the 5 respective sides of the soffit and extrados.