BRPI0905265A2 - aerodynamic conversion of wind energy - Google Patents

Abstract

AERODYNAMIC CONVERSION OF WIND ENERGY. Modality: Internal Flow to the Collector and Concentrator Panel - System of collector panel and airstream concentrator, 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 reduction 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. Given 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 alignment of the panel with the wind and maintain an ideal angle of attack. Under certain construction limits, 2 (two) or more panels may be superimposed vertically, doubling or more the catchment area and the consequent conversion, while maintaining the optimum 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 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 occur through windows with movable blades, for the purpose of differential counter flow retainers, allowing the air entry 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 that converts 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

"AERODYNAMIC CONVERSION OF WIND ENERGY"

The present invention relates to a system of harnessing energy in drafts, called wind energy, through deflector panels, collectors and concentrators of airflow, or devices with similar effects, fixed or semi-fixed, capturing, conducting and accelerating the current. , to convert its energy into useful and controlled forms of utilization, by means of air turbines (s) installed in the section of higher concentration of the air flow or other, section that proves to be more favorable, being this turbine driven by the current internal to the panel. , which is formed by the circulation between the inside and outside when the panel is exposed to the wind.

Defined collector panels, or devices with similar effect, fixed or semi-fixed, may be associated in connection with each other to result in the capture of increased volumes and concentrations of air flow, with the result of increased utilization.

Large freely moving air masses, even at moderate speeds, have a considerable amount of energy, but as they are dispersed, the energy is diffused and its large-scale utilization will, however, depend on interference in large areas in airspace, which it seems out of practical reach in simultaneous capture and conversion by pinwheels only.

Thus, the present invention proposes a wind energy aerodynamic conversion system, involving usual construction methods and known principle-based operation process, depending on its effective demonstration of operation and effectiveness, experimentation and theoretical analysis that optimize the configuration of the joint and its components, aiming at effective operation and economic efficiency.

The proposed system is based on the separation of the capture functions from the wind energy conversion functions, whose characteristics are in summary:

- PRINCIPLE - Separation of the retrofitting and energy conversion functions.

- METHOD - Use of fixed or semi-fixed elements, such as interference panels in large areas of air space, to capture the energy of large amounts of moving air, generating a useful flow for energy conversion through compact I - turbine (s). and proportionally low inertia.

- ADVANTAGES - Untying of mobile elements to capture wind energy (pinwheels), which seem to be limited in size and cost, leading to the formation of parqueseolics.

- (a) The separation of the conversion functions of conversion allows the capture of large moving air masses by means of fixed or semi-fixed panels of large size, but mechanically and structurally simple and rigid and presumably economical.

- (b) As for the conversion of the energy captured (utilization), it allows the use of a proportionally compact and efficient power unit (air turbine) with less inertia and predictable reduction of significant limitations.

- (c) Pick-up and conversion stations do not require complex technology and resources, and can be split up by various suppliers, facilitating acquisition and may reduce construction time and costs,

- GENERAL SYSTEM MODEL:

- 1) Characteristics: The combination of panels and air turbines, adapted for each manufacturer, will allow them to be reduced in size for a given power, as they will be exposed to concentrated, larger and faster drafts by the baffle panels and concentrators of the chain.

Interference panels will be able to serve from a height stand for the installation of multiple air turbines, reaching large above-ground catchments, thus reaching scattered air masses, but carrying appreciable amounts of diffuse energy.

The farther from the ground, rising air will be less affected by its influence and, therefore, subjected to higher speed and energy, which may improve the cost / benefit ratio for converting energy into controlled uterine utilization.

- 2) Drawings and illustrations without scale:

Figure 1 - Lateral elevation of the collector panel and concentrator;

Figure 2 - Typical section of the paineleol;

Figure 3 - Illustration of the typical panel section, in cross section;

Figure 4 - Front and side elevation with indications of anchorage and flow in the wind chamber Figure 5 - Front elevation with indication of wind flow in the air chamber and exhaust and intake windows;

Figure 6 - Illustration of the lateral elevation system, with indication of stays:

Figure 7 - Schematic illustration perspective of a typical collector panel module;

Figure 8 - Internal view - collector panel and concentrator extractor;

Figure 9 - Internal View - Extraction, indicating modules and tapering of the flow channel;

Figure 10 - Internal view - intruder of the collector and concentrator panel, indicating an input window with flow retention:

Figure 11 - Internal view - intradorsode of the collecting and concentrating panel, indicating modules, flow tapering and concentrated and accelerated flow.

Claims (10)

1.) "AERODYNAMIC CONVERSION OF WIND DEENERGY" is characterized as a windshield interference panel (s), with the functions of deflecting, collecting, concentrating and accelerating an internal airflow (s). by directing the resultant to the air turbine (s) associated with the panel (s) in order to convert its energy (wind energy) into useful and unmanaged harnessing forms. The accompanying figures 1, 8 and 10 describe a typical panel and the association with wind turbine air turbine, object of the present patent, in which: Fig. 1 shows, lateral elevation of the wind panel, describing the system and typical transverse section, including the following telltale signs corresponding to each descriptive detail: (1) Concentrator Collector Panel (Title) (2) Airflow Slits (3) Wind Chamber (4) Air Turbine (5) Anchors - Fixed or Movable (6) Base anchor (7) Wind (8) SoloA Fig 8 shows lateral elevation of the wind panel with internal view of the extractor, including the following indicator signals corresponding to each descriptive detail: (1) Collector and concentrator panel - Internal view - Extractor (2) Flow slots Air - Outlet - Extractor (3) Modules (4) WindA Fig. 10 shows lateral elevation of the wind panel with internal view of the intractor, including the following indicator signals corresponding to the descriptive profile: (1) Panel with switch and concentrator - Internal view - Soffit (2) Modules (3) Inlet / Backflow Retention window (4) Airflow slots - Inlet - soffit (5) Drainage reduction (6) Typical Module ( 7) Concentrated and accelerated flow (8) Wind 2.) The airflow internal to the panel is characterized as formed by the action of the wind current, affecting the positive attack angle from top to bottom over its cross sections, as typical illustrations in the following figures: Fig. 2 showing the cross section of the wind panel, including the following telltale signs of each descriptive detail: (1) Cross Section Profile (Title) (2) Zone Separation Diaphragm (3) Lead Angle (4) Deflected Airstream (5) Pressure distribution - sill (6) Flow taper plate (7) Pressure distribution - sill (8) Maximum suction (9) Suction slot (10) Air outlet (11) Counter control window flow (12) Pressure zone (13) Maximum pressure (14) Pressure slot (15) Air inlet (16) Suction zoneFig. 7 showing the schematic illustration perspective of a typical wind panel, manifold / concentrator module, including the following indicative signals of each descriptive detail: (1) Typical module perspective (Title) Thus through air inlet slots, respectively through pressure. on the inside and out by suction on the outside, established by the deflection of the wind current, aracelerated and concentrated flow is formed towards the turbine (s). 3.) Internally to the cross sections, there is a division which is characterized by separating diaphragm of the pressure and suction zones, as detailed (2) in figure 2 described in item 4 of the present Claim, only allowing communication between the same through the wind chamber and its associated air turbine, installed at the end of the panel or possibly at any other point which is more constructively favorable or the air flow. 4.) In the air flow path characterized along the panel, counterflow windows are installed in the pressure zone, as shown in figure 2, operating with differential action blades or equivalent effect device to allow inlet air to pass through only if the internal static pressure is less than the total external inlet pressure, as shown in the illustration: Fig. 2 showing the typical cross section of the wind panel, including the following telltale signs of each descriptive detail: (1) Cross Section Profile (Title) (2) Zone Separation Diaphragm (3) Lead Angle (4) Draft deflected (5) Pressure distribution - sill (6) Flow taper plate (7) Pressure distribution - sill (8) Maximum suction (9) Suction slot (10) Air outlet (H) Back control window flow (12) Pressure zone (13) Maximum pressure (14) Pressure slot (15) Air inlet (16) Suction zone 5.) It is characterized to reduce the internal static pressure in the pressure zone, to be installed progressive reduction plates of the internal flow passage area, tapering the folding, as illustrated in the following figure 3, and also the figures- 4, 5, 9 and 11 illustrating the construction of the panel (s) with the air chamber (s) air turbine combination (s): Fig. 3 shows on the collector and concentrator wind panel the cross section of the typical module -cut, including the following descriptive step indicator signals: (1) Cross-sectional profile (Title) (2) Zone separation diaphragm (3) Lead angle (4) Deflected airflow (5) Pressure distribution - Sink (6) Drainage reduction plate (7) Pressure distribution - Extractor (8) Maximum suction (9) Suction slot (10) Air outlet (Π) Counterflow inlet and hold window (12) Pressure zone (13) Maximum pressure (14) Pressure slot Noon (15) Air inlet (16) Suction zoneA Fig 4 - shows the front and side elevation of the windshield collector panel, with anchor and flow indications in the wind chamber, including the following telltale signs of each descriptive detail :( 1) Collector Modules (2) Airflow Slit - Extractor Outlet (Suction) (3) Airflow Slot - Intrahorse Inlet (Pressure) (4) Base Module - Flow Connection, Anchor and TurbineConverter (5) ) Anchorages - Fixed or Movable (6) Wind Turbine and Converter Turbine (7) Intake Window (8) Exhaust WindowA Fig. 5 - shows front elevation of the collector and concentrator wind panel, with air flow indication in the wind and exhaust windows and inlet, including the following telltale signs of each descriptive detail: (1) Collector module (2) Airflow slots - Extractors outlet (Suction) (3) Airflow slots - Intake ports (Pressure ) (4) Base Module - Connection flow, Anchor and Chamber (5) Anchorages - Fixed or Movable (6) Wind Turbine and Converter Turbine (7) Intake Window (8) Exhaust WindowA Fig. 9 - shows the inside view - Extraction, indicating Modules and Channel Funneling and center wind collector panel flow rate, including the following telltale signs of each descriptive detail: (1) Collector and concentrator panel - Internal view - Extractor (2) Airflow slot - Output - Extractor (3) Modules (4) flow channel (5) Typical module (6) Soil (7) WindA Fig 11 shows the inside view of the collector and center wind turbine panel indicating modules, concentrated and accelerated flow channel bottlenecks, including the following telltale signals for every detail Description: (1) Collector Panel and Concentrator - Internal View - Soffit (2) Modules (3) Inlet Windows (Backflow Retention) (4) Airflow Slit - Inlet - Soffit (5) Ca Taper flow (6) Typical module (7) Concentrated and accelerated flow (8) Soil (9) Wind 6.) For the turbine (s) the energy converter (s) associated with the panel (s) which may preferably be supplied by the specialized manufacturers, but adapted (s) to the design specifications of the "Wind Energy Aerodynamic Conversion" but, if necessary, taking into account its own design and patent. 7.) The construction of the collector panel (s) is characterized as planned in separate modules, to be installed superimposed, firmly connected to each other from the top to the bottom of its construction, whose executive design, including with constructive alternative in In relation to the division by modules, it should be defined according to the dimensions to be specified for each application, according to their respective definitions. 8.) Each panel is characterized as having to be supported in an anchor base by means of a base module, having mobility and swivel drive by motorized or manual mechanism, ensuring the alignment with the wind, controlled or indicated by sensor (s), in order to Maintain or correct the optimal angle of attack to capture and convert wind energy. Alternatively, the panel support may be fixed or semi-fixed, depending on expected changes in wind direction. Following are illustrations with figures 4 and 5: Fig. 4 shows the front and side elevation of the windshield and collector wind panel, with indications of anchorage and flow in the wind chamber, including the following telltale signs of each descriptive detail: (1) Collector module (2) Airflow slots - Exit at Extraction (Suction) (3) Airflow slots - Intake (Pressure) inlet (4) Base module - Flow, Anchorage and TurbineConverter (5) Anchors - Fixed or Movable (6) Wind Turbine and Converter Turbine (7) Intake window (8) Exhaust windowFigure 5 shows the front elevation of the collector and concentrator wind panel, with indication of airflow in the wind chamber and exhaust exhaust windows, including the following telltale signs of each detailed description. : (1) Collector module (2) Airflow slots - Extractor outlet (Suction) (3) Airflow slots - Intrahorse (pressure) inlet (4) Base module - Flow fitting, Anchor and Chamber (5) Anchorages - Fixed or Furniture (6) Wind Turbine and converter turbine (7) Intake window (8) Exhaust window 9.) The lateral aerodynamic load that will be resisted by the stanchion (s) connected to the panel by cables with sliding termination sliding on a stanchion rail of preference l / 3 (one third) and 2/3 (two thirds) in height is characterized. Fig. 6 illustrates the staging device, showing lateral elevation of the wind panel, describing the system for aerodynamic conversion of wind energy and the typical cross section, including the following signals indicating each descriptive detail: (1) Anchorages - Fixed and mobile (2) Airflow slots - Inlet and Outlet Exit (3) Stem Rail (4) Stations (5) Wind Chamber (6) Turbinaaar (7) Dock (8) Ground (9) Wind 10.) The claimed invention is characterized by the use of panel (s) for interference in wind currents, equipped with special configurations, associated with air turbine (s), presenting the innovation of separating the functions of uptake of energy conversion to allow large air masses to be achieved by moving with diffuse wind energy regardless of mobile elements and thus converting wind energy through turbine (s) to specially adapted (s) which will be proportionally compact (s) ) are more efficient, with less inertia and predictable reduction of significant limitations. Thus defined fixed or mobile collector panels may also be combined in connection with each other to result in the capture of increased volumes and concentrations of air flow and thus to take advantage of increased wind energy.