CN117927411A - Wind power generation system suitable for roof - Google Patents

Abstract

The invention discloses a wind power generation system suitable for a roof, which comprises: an external airflow channel which is surrounded by the top plate, the bottom plate and the side wing plates and is provided with an air inlet and an air outlet; an internal airflow channel formed by a U-shaped pipeline and a fan pipeline, wherein the U-shaped pipeline is provided with an opening, and a generator component is arranged in the fan pipeline; in the same horizontal projection plane, the depth of the U-shaped pipeline is d1, the vertical distance from one end of the side wing plate adjacent to the U-shaped pipeline to the bottom tangent line of the U-shaped pipeline is d2, the vertical distance from the central line of the U-shaped pipeline to the outermost side of the U-shaped pipeline is h1, the horizontal distance from the outermost side of the U-shaped pipeline to the innermost side of the adjacent side wing plate is h2, and the following relation is satisfied: 0.25d1+.d2+.0.5d1, 0.5h1+.h2+.h1. The wind power generation system structure disclosed by the invention can improve the conversion ratio of wind speed, thereby improving the power generation efficiency.

Description

Wind power generation system suitable for roof

Technical Field

Embodiments of the present disclosure relate generally to the field of wind power generation technology, and more particularly, to a wind power generation system suitable for rooftops.

Background

The kinetic energy of the air flow is called wind energy, the utilization of the wind energy is to convert the kinetic energy of the air movement into other forms of energy, such as windmills, sails and the like, which are all devices for converting the wind energy into mechanical energy, and the wind energy is taken as a power source to replace manpower and animal power, thereby playing an important role in the development of productivity. Because electric power has become a necessity for modern people to produce and live, wind power generation is utilized to convert wind energy into electric energy, and the electric energy is a main utilization form of modern wind energy.

The wind power generator extracts energy from wind through the turbine, and the limit ratio of the energy converted from wind energy to kinetic energy is 16/27 and is about 59% according to the betz law, and the wind energy conversion is directly proportional to the air density, the area swept by the turbine and the square of the wind speed. Because the mass flow of air passes through the area swept by the turbine, and the mass flow and the wind speed are linearly increased along with the change of the wind speed and the density of the air, the wind energy effective to the turbine is in direct proportion to the cube of the wind speed, and one of the key points of the wind power generation technology is how to capture the larger wind speed, so that the power generation efficiency is improved.

Disclosure of Invention

The invention aims to provide a wind power generation system suitable for a roof, which solves the problems of small wind speed conversion rate and low power generation efficiency of the wind power generation system used for the roof through a generator.

In order to solve the technical problems, the invention adopts the following technical scheme:

The present disclosure provides a wind power generation system suitable for a roof, comprising: the outer air duct assembly comprises a top plate, a bottom plate and a side wing plate connected between the top plate and the bottom plate, wherein the top plate, the bottom plate and the side wing plate jointly enclose an outer air flow channel with an air inlet and an air outlet, and the outer air flow channel is of a diffusion structure from the air inlet to the air outlet; the inner air duct assembly comprises a U-shaped pipeline and a fan pipeline which are mutually communicated, wherein the U-shaped pipeline and the fan pipeline which are mutually communicated form an inner air flow channel, the side wing plates are symmetrically distributed on two sides of the U-shaped pipeline, the U-shaped pipeline is provided with an opening, the opening is positioned at a windward opening of the outer air flow channel, the direction of the opening is opposite to the direction of the windward opening, the fan pipeline is provided with an air inlet which is communicated with the opening, and a generator assembly is arranged in the fan pipeline; in the same horizontal projection plane, the depth of the U-shaped pipeline is d1, the vertical distance from the U-shaped end part of the side wing plate adjacent to the U-shaped pipeline to the bottom tangent line of the U-shaped pipeline is d2, the vertical distance from the central line of the U-shaped pipeline to the outermost side of the U-shaped pipeline is h1, and the horizontal distance from the outermost side of the U-shaped pipeline to the innermost side of the adjacent side wing plate is h2, so that the following relation is satisfied: 0.25d1+.d2+.0.5d1, 0.5h1+.h2+.h1.

In some embodiments d1=0.5 m to 1.5m.

In some embodiments, h1=0.25 m to 0.75m.

In some embodiments, the air intake is oriented the same as the windward.

In some embodiments, the wind power generation system further comprises: a base; the rotary support is characterized in that an outer ring of the rotary support is fixed on the base, the U-shaped pipeline is connected with the fan pipeline through a transition pipeline, and the transition pipeline and the bottom plate are both fixed on an inner ring of the rotary support, so that the outer air duct component and the inner air duct component can follow the inner ring to rotate relative to the outer ring together, and the direction of the air inlet and the windward opening can be adjusted.

In some embodiments, the fan duct is cylindrical, a lower end nozzle of the transition duct is in matched engagement with an upper end nozzle of the fan duct, an upper end nozzle of the transition duct is in matched engagement with a lower end duct of the U-shaped duct, wherein the lower end nozzle of the transition duct is larger than the upper end nozzle of the transition duct.

In some embodiments, the ratio of the height of the transition duct to the diameter D of the circular cross section of its lower end is greater than 1.

In some embodiments, the product of the chord length B and the height L of the side panels is more than 20 times the swept area of the wind turbine.

In some embodiments, the cross section of the side wing plate is in a shape of a round head and a pointed tail, a round front edge of the round head faces in the wind direction, and the bending degree of the inner surface of the side wing plate is larger than that of the outer surface.

In some embodiments, the ratio of the height L of the flanks to the chord length B is greater than 2.

In some embodiments, the angle alpha between the chord line of the side wing plate and the horizontal wind direction is less than 15 degrees, and the ratio of the width d of the U-shaped pipeline to the width W of the windward opening is not less than 0.5.

The technical scheme of the invention has at least the following technical effects: through the optimization of the structure, the positions of all the components and the distances of the wind power generation system suitable for the roof, when the equivalent external wind speed passes through the external airflow channel, the wind speed conversion of the external airflow when the external airflow induces the air to accelerate in the internal airflow channel is higher, so that the power generation efficiency is greatly improved.

Drawings

For a clearer description of embodiments of the present invention, reference will be made to the accompanying drawings, which are only some embodiments of the present invention, and from which other drawings can be obtained by a person skilled in the art, for the purpose of describing the embodiments of the present invention briefly. These drawings are provided to facilitate the reader's understanding of the disclosed technology and should not be considered limiting of its breadth, scope or applicability.

FIG. 1 is a schematic perspective view of a wind power generation system suitable for use on a roof;

FIG. 2 is a schematic front view of a wind power generation system suitable for use on a roof;

FIG. 3 is a schematic side view of a hidden wind power generation system suitable for use on a roof in accordance with the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 3 at I;

FIG. 5 is a perspective view of a base;

FIG. 6 is a schematic perspective view of an inner duct assembly;

FIG. 7 is a schematic cross-sectional view of an inner air duct assembly;

FIG. 8 is a schematic perspective view of a transition duct;

FIG. 9 is a schematic cross-sectional perspective view of a transition duct;

FIG. 10 is a schematic view of a side panel construction;

FIG. 11 is a schematic view of the distribution of the flanks;

FIG. 12 is a side view of a top plate in an airfoil configuration with the addition of a baffle above the bottom plate;

FIG. 13 is a schematic illustration of the addition of baffles outside the U-shaped conduit;

fig. 14-29 are graphs of simulated data of wind speed through a fan under different conditions.

In the figure: 100. top plate, 101, airfoil top plate, 102, leading edge, 103 upper surface, 104 lower surface, 200, side wings, 204 chords, 205, leading edge, 206, inner surface, 207, outer surface, 300, bottom plate, 301, deflector, 400, U-shaped duct, 401, cambered side, 402 open side, 403 deflector, 500, transition duct, 501, upper end face, 502, lower flange, 503, lower end face, 600, base, 601, mesa, 602, swing track, 603, bracket, 604, slider, 605, base flange, 700, swing support, 701, outer ring, 702, inner ring, 703 bolts, 704, bolts, 800, generator assembly, 900, fan duct, 901, duct upper flange, 902, duct lower flange, 110, air intake, 111 open side, 120, locking pins.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention are clearly and completely described below. It will be apparent that the described embodiments are some, but not all, embodiments of the invention. All other embodiments, which can be made by a person skilled in the art without creative efforts, based on the described embodiments of the present invention fall within the protection scope of the present invention.

The technical scheme of the present invention is further explained and illustrated below with reference to specific examples.

As shown in fig. 1-12, the present disclosure provides a wind power generation system suitable for use on a roof, including an outer air duct assembly and an inner air duct assembly. The outer air duct assembly comprises a top plate 100, a bottom plate 300 and a side wing plate 200 connected between the top plate 100 and the bottom plate 300, wherein the top plate 100, the bottom plate 300 and the side wing plate 200 jointly enclose an outer air flow channel with an air inlet and an air outlet, and the outer air flow channel is of a diffusion structure from the air inlet to the air outlet.

The inner air duct assembly comprises a U-shaped pipeline 400 and a fan pipeline 900 which are mutually communicated, the U-shaped pipeline 400 and the fan pipeline 900 form an inner air flow channel, the side wing plates 200 are symmetrically distributed on two sides of the U-shaped pipeline 400, the U-shaped pipeline is provided with openings, the openings are positioned at the windward openings of the outer air flow channel, and the directions of the openings are opposite to the directions of the windward openings. In a preferred embodiment, the opening extends along the height of the U-shaped channel, and the opening may have an extension of less than or equal to the height of the U-shaped channel, for example, the opening may extend about half the height of the U-shaped channel, or the opening may have an extension of about the height of the U-shaped channel.

The fan duct 900 has an air inlet 110 in communication with the opening, and a generator assembly 800 is disposed within the fan duct 900. The front edges of the two side wings 200 may form the windward opening of the external airflow channel, with the opening direction of the windward opening facing the incoming direction and the opening direction of the U-shaped duct facing away from the incoming direction. The windward opening may be the narrowest throat location of the outer airflow channel. When external wind blows through the external airflow channel, the external airflow induces the air to accelerate in the internal airflow channel under the effect of Bernoulli effect, so that the energy is provided for the generator to generate electricity.

As shown in fig. 11, in the same horizontal projection plane, the depth of the U-shaped pipe 400 is d1, the vertical distance from one end of the side wing plate 200 adjacent to the U-shaped pipe 400 to the tangent line of the U-shaped end of the U-shaped pipe 400 is d2, the vertical distance from the center line o of the U-shaped pipe 400 to the outermost side of the U-shaped pipe 400 is h1, and the horizontal distance from the outermost side of the U-shaped pipe 400 to the innermost side of the adjacent side wing plate 400 is h2, which satisfies the following relationship: 0.25d1+.d2+.0.5d1, 0.5h1+.h2+.h1.

Through the optimization limitation of the structural parameters, experiments prove that when the equivalent external wind speed passes through the external airflow channel, the wind speed of the air in the internal airflow channel caused by the external airflow can be maximized, so that the power generation efficiency is greatly improved.

Specific experimental data are as follows:

14-29, wherein FIGS. 14 and 15 are respectively the continuous wind speed plane distribution map and the wind speed vector distribution map generated in the fan of group 1, and FIG. 16 is the equivalent simulation data analysis of the fan of group 1 through the plane distribution map and the vector distribution map. Fig. 16-29 are equivalent simulation data analyses of different sets of through plane and vector profiles, respectively.

From the above table and the corresponding simulation diagram, it can be seen that in the 1 st, 2 nd, 3 rd, 10 th, 11 th and 12 th data in the range of 0.25d1+.d2+.0.5d1, 0.5h1+.h2+.h1, the wind speed when passing through the engine is all above 7.5m/s, therefore, under the design of the structural parameter, the conversion ratio of the wind speed can be above 1.5 times, the wind speed is obviously improved, the power generation efficiency under the structure is higher, and thus, good economic benefits can be obtained. In contrast, in the 8 th, 9 th, 13 th, 14 th, 15 th to 20 th data which are not in the range of 0.25d1+.d2+.0.5d1 or 0.5h1+.h2+.h1, the wind speed of the engine is mostly lower than 7m/s, the wind speed conversion ratio is about 1.2 times in most cases, the power generation efficiency is lower, and the actual requirements are hardly satisfied.

In some embodiments, d1 is 0.5m to 1.5m. From the table and the corresponding simulation diagram, it can be seen that in the data of the 1 st group, the 2 nd group, the 3 rd group, the 10 th group, the 11 th group and the 12 th group in the range of d1=0.5 m-1.5 m, the wind speed of the engine is over 7.5m/s, the conversion ratio of the wind speed can be over 1.5 times, the wind speed is obviously improved, and the power generation efficiency under the structure is higher, so that good economic benefit can be obtained. In a preferred embodiment, d1 is from 1m to 1.5m. In contrast, in the 4 th and 5 th data sets not within the d1=0.5 m to 1.5m range, the engine wind speed is only about 6m/s, and the wind speed conversion ratio is about 1.2 times, and the power generation efficiency is low.

In some embodiments, h1 is 0.25m to 0.75m. From the table and the corresponding simulation diagram, it can be seen that in the data of the 1 st group, the 2 nd group, the 3 rd group, the 10 th group, the 11 th group and the 12 th group in the range of 0.25 m-0.75 m, the wind speed of the engine is over 7.5m/s, the conversion ratio of the wind speed can be over 1.5 times, the wind speed is obviously improved, and the power generation efficiency under the structure is higher, so that good economic benefit can be obtained. In a preferred embodiment, h1 is from 0.5m to 0.75m. In contrast, in the data of the 6 th and 7 th groups, which are not in the range of h1=0.25 m to 0.75m, the engine wind speed is only about 6m/s, and the wind speed conversion ratio is about 1.2 times, so that the power generation efficiency is low, and the actual requirements are hardly satisfied.

In some embodiments, the orientation of the air inlet 110 is the same as the orientation of the windward opening. For example, the wind speed passing through the fan is further improved by leading the air to enter the air flow channel and leading the air to accelerate in the air flow channel by the external air flow in the internal air flow channel, so that the power generation efficiency is improved.

As shown in fig. 10, the side wing panel 200 is integrally formed of a skin 201, ribs 202 and posts 203, the skin 201 functioning to form a streamlined smooth surface; the rib 202 has several layers for supporting the skin 201 to maintain the cross-sectional shape of the side panel 200; the upright 203 is a series connection element of a plurality of layers of rib plates, and at the same time, the upper end and the lower end of the upright 203 are respectively connected with the top plate 100 and the bottom plate 300.

As shown in fig. 4-7, in some embodiments, the wind power generation system further comprises: the base 600 and the rotary support 700, the outer ring 701 of the rotary support 700 is fixed on the base 600, the U-shaped pipeline 400 and the fan pipeline 900 are connected through the transition pipeline 500, and the transition pipeline 500 and the bottom plate 300 are both fixed on the inner ring 702 of the rotary support 700, so that the outer air duct assembly and the inner air duct assembly can rotate together with the inner ring 702 relative to the outer ring 701, and the orientation of the air inlet 110 and the air inlet is adjusted.

In some embodiments, the blower tube 900 is cylindrical, and the lower end orifice of the transition tube 500 is in mating engagement with the upper end orifice of the blower tube 900, and the upper end orifice of the transition tube 500 is in mating engagement with the lower end tube of the U-shaped tube 400, wherein the lower end orifice of the transition tube 500 is larger than the upper end orifice of the transition tube 500. The effect of the Bernoulli effect can be improved through the transition pipeline structure with the wide bottom and the narrow top, and the conversion ratio of wind speed can be improved.

As shown in fig. 4-7, for example, the outer ring 701 of the slewing bearing 700 is fixed on the base flange 605 above the table-board 601 of the base 600, the inner ring 702 penetrates the base table-board 601, and the bottom plate 300 and the lower flange of the transition duct 500 are both fixed on the upper end surface of the slewing bearing inner ring 702; a swing rail 602 is provided above the base table 601 to support the base plate 300, and the base plate 300 is moved along the swing rail 602 by a slider 604 fixed therebelow; the lower end surface of the inner ring 702 of the slewing bearing 700 is connected with a cylindrical pipeline 900, and the lower end of the cylindrical pipeline (fan pipeline) 900 is connected with an air inlet 110; in windy conditions, the bottom plate 300, the upper side wing plates 200, the top plate 100, the transition pipeline 500, the U-shaped pipeline 400, the cylindrical pipe 900 and the air inlet 110 synchronously revolve around the outer ring 701 of the slewing bearing 700 so as to ensure the relative positions of the inner flow channel and the outer flow channel to achieve the optimal hydrodynamic performance.

In one embodiment, to avoid the problem of line winding caused by repeated wind-up, the base plate 300 may be locked with the swivel rail above the base 600 by the locking pins 120 after the main wind direction is determined according to the local monsoon characteristics.

The cambered surface side 401 of the U-shaped pipeline 400 and the open side of the windward opening face the wind direction, and the opening 402 of the U-shaped pipeline faces the direction of leaving wind, namely faces away from the wind direction.

The upper end and the lower end of the cylindrical pipeline 900 are respectively provided with a connecting flange, the upper flange 901 is fixed with the lower end surface of the slewing bearing inner ring 702 through bolts 704, and the lower flange 902 is connected with the air inlet 110 through bolts 705.

The air inlet 110 is of an open structure as a whole, the open side 111 faces the incoming wind direction, a circular hole is formed in the position, which is relatively rear, of the upper end face, the size of the hole is consistent with that of the cylindrical pipeline 900, and the lower flange 902 of the cylindrical pipeline 900 is fixed to the outer edge of the hole through bolts 705.

The transition pipeline 500 is a section of pipeline which is in U-shaped transition to be cylindrical, is connected with the U-shaped pipeline 400 through the upper end surface 501, is welded or connected in a flange mode, and can be designed to be an integral body with the U-shaped pipeline of the transition pipeline.

The transition pipe is provided with a lower flange 502 which is positioned above the bottom plate 300, and the bottom plate 300 is fixed on the upper end surface of the slewing bearing inner ring 702 by sharing a set of fixing bolts 703.

In some embodiments, the ratio of the height of the transition duct 500 to its lower circular cross-sectional diameter D is greater than 1.

In some embodiments, the chord length B of the side panel 200 multiplied by the height L is more than 20 times the swept area of the wind turbine.

In some embodiments, as shown in fig. 10, the ratio of the height L of the side wing plate to the chord length B is greater than 2, so that the wind passing efficiency of the side wing plate is optimized, and the effect of the bernoulli effect can be improved.

In some embodiments, as shown in fig. 11, the included angle α between the chord line of the side wing plate and the horizontal wind direction is smaller than 15 °, the ratio of the width d of the U-shaped pipeline to the width W of the windward opening is not smaller than 0.5, and by this structure, the wind passing efficiency of the side wing plate can be optimized as well, and the bernoulli effect can be improved.

In some embodiments, the cross-section of the side panels 200 is rounded nose-to-tail with the rounded leading edge of the nose facing in the direction of the incoming wind and the curvature of the inner surface of the side panels is greater than the curvature of the outer surface.

In some embodiments, the cross-section of the side panel 200 is rounded nose-tail with a rounded leading edge surface 205 facing in the direction of the incoming wind, the camber of the inner surface 206 of the side panel 200 being greater than the camber of the outer surface 207 thereof; the side wing plates are symmetrically distributed at the rear side of the U-shaped pipeline 400, the included angle between the side wing plate chord line 204 and the wind direction, namely the attack angle alpha, is smaller than 15 degrees, and the ratio of the width d of the U-shaped pipeline to the width W of the windward side is not smaller than 0.5. The wind passing efficiency of the side wing plate can be optimized through the structure, and the Bernoulli effect can be improved.

In some embodiments, as shown in fig. 13, a baffle 403 may be added to the outer sidewall of the U-shaped pipe 400 to improve the hydrodynamic characteristics of the external flow channel, thereby improving the wind speed conversion ratio and improving the power generation efficiency. For example, a plurality of U-shaped deflectors 403 may be uniformly distributed along the height direction of the outer side wall of the U-shaped duct 400, so that the incoming wind may be more uniformly directed to the openings of the U-shaped duct 400, and the incoming wind passing through the openings at various positions along the height direction of the duct 400 may be more uniform, so as to improve the hydrodynamic characteristics of the external flow channel, thereby improving the wind speed conversion ratio and the power generation efficiency.

In other embodiments, as shown in fig. 12, a baffle 301 may be added to the base plate 300 on two opposite sides of the U-shaped pipe 400, where the baffle 301 has an arc-shaped guiding surface, and the guiding surface guides the incoming wind in the direction of the opening of the U-shaped pipe 400, so as to improve the hydrodynamic characteristics of the external flow channel, thereby improving the wind speed conversion ratio and improving the power generation efficiency.

Although the embodiments of the present invention are described above, the embodiments are only used for facilitating understanding of the present invention, and are not intended to limit the present invention. Any person skilled in the art can make any modification and variation in form and detail without departing from the spirit and scope of the present disclosure, but the scope of the present disclosure is to be determined by the appended claims.

Claims (10)

1. A wind power generation system adapted for use on a roof, comprising:

The outer air duct assembly comprises a top plate, a bottom plate and a side wing plate connected between the top plate and the bottom plate, wherein the top plate, the bottom plate and the side wing plate jointly enclose an outer air flow channel with an air inlet and an air outlet, and the outer air flow channel is of a diffusion structure from the air inlet to the air outlet;

The inner air duct assembly comprises a U-shaped pipeline and a fan pipeline which are mutually communicated, wherein the U-shaped pipeline and the fan pipeline form an inner air flow channel, the side wing plates are symmetrically distributed on two sides of the U-shaped pipeline, the U-shaped pipeline is provided with an opening, the opening is positioned at the windward opening of the outer air flow channel, the direction of the opening is opposite to the direction of the windward opening, the fan pipeline is provided with an air inlet communicated with the opening, and a generator assembly is arranged in the fan pipeline;

In the same horizontal projection plane, the depth of the U-shaped pipeline is d1, the vertical distance from one end of the side wing plate adjacent to the U-shaped pipeline to the tangent line of the U-shaped end of the U-shaped pipeline is d2, the vertical distance from the central line of the U-shaped pipeline to the outermost side of the U-shaped pipeline is h1, and the horizontal distance from the outermost side of the U-shaped pipeline to the innermost side of the adjacent side wing plate is h2, so that the following relation is satisfied: 0.25d1+.d2+.0.5d1, 0.5h1+.h2+.h1.

2. Wind power generation system according to claim 1, characterized in that d1=0.5 m-1.5 m.

3. Wind power generation system according to claim 2, characterized in that h1=0.25 m-0.75 m.

4. The wind power generation system of claim 1, wherein the wind inlet is oriented in the same direction as the windward opening.

5. The wind power generation system of claim 1, further comprising: the wind turbine comprises a base and a rotary support, wherein an outer ring of the rotary support is fixed on the base, a U-shaped pipeline is connected with a fan pipeline through a transition pipeline, and the transition pipeline and a bottom plate are both fixed on an inner ring of the rotary support, so that the outer air duct component and the inner air duct component can follow the inner ring to rotate relative to the outer ring together, and the direction of an air inlet and an air inlet can be adjusted.

6. The wind power generation system of claim 5, wherein the fan duct is cylindrical, a lower end nozzle of the transition duct is in mating engagement with an upper end nozzle of the fan duct, an upper end nozzle of the transition duct is in mating engagement with a lower end duct of the U-shaped duct, and wherein the lower end nozzle of the transition duct is larger than the upper end nozzle of the transition duct.

7. The wind power generation system of claim 6, wherein the ratio of the height of the transition duct to the diameter D of the circular cross section at its lower end is greater than 1.

8. A wind power generation system according to claim 1, wherein the cross section of the side wing plate is in the shape of a rounded nose and a rounded front edge of the rounded nose faces in the direction of wind, and the camber of the inner surface of the side wing plate is greater than the camber of the outer surface.

9. Wind power system according to claim 1, wherein the ratio of the height L of the flanks to the chord length B is greater than 2.

10. The wind power generation system according to claim 1, wherein an angle α of a chord line of the side wing plate to a horizontal wind direction is less than 15 °, and a ratio of a width d of the U-shaped duct to a width W of the windward opening is not less than 0.5.