CN113969874A

CN113969874A - Special guiding device of intelligence wind field

Info

Publication number: CN113969874A
Application number: CN202111263610.7A
Authority: CN
Inventors: 侯迎彬; 柯雄; 郭晓晓; 韩国强; 师岩哲
Original assignee: PowerChina Hebei Electric Power Engineering Co Ltd
Current assignee: PowerChina Hebei Electric Power Engineering Co Ltd
Priority date: 2021-10-28
Filing date: 2021-10-28
Publication date: 2022-01-25
Also published as: WO2023071006A1

Abstract

The invention discloses a special flow guide device for an intelligent wind field, which belongs to the technical field of flow guide of the intelligent wind field and comprises 2 bearing seats arranged in parallel, a plurality of parallel slide rails connected with the bottom ends of the bearing seats in a sliding manner, 2 wind field wind collecting structures respectively arranged at the upper ends of the 2 bearing seats, a flow guide structure arranged on the left side among the 2 bearing seats and capable of changing the wind direction for flow guide, a wind shielding buffer structure arranged on the right side among the 2 bearing seats and a cylinder fixedly connected to one end of the inner side of the bearing seat; the cylinder pushes the bearing seat to move and adjust on the sliding rail; when the diversion direction needs to be changed, the wind shielding buffer structure can reduce the energy consumption of the diversion structure. The wind channel of the wind power flow guide is small in limitation, simple and convenient to install or disassemble and small in energy consumption, and the practicability of the flow guide structure is effectively improved.

Description

Special guiding device of intelligence wind field

Technical Field

The invention relates to the technical field of intelligent wind field diversion, in particular to a special diversion device for an intelligent wind field.

Background

With the acceleration of the digital and intelligent construction of the new energy industry, no person is on duty and few people are on duty, the new energy industry becomes more and more the future trend of the development of the wind power plant, such as: in a certain wind power plant in the Xuan city of Anhui province, 45 fans are distributed on a mountain range between a south ripple lake and a Gucheng lake, and good economic benefit is brought to the wind field with the installation of nearly 10 ten thousand kilowatts due to good wind power formed by thermal circulation between the lake and the mountain range.

The intelligent wind field uses and need use the water conservancy diversion structure to guide wind-force of wind field, current wind field guiding device snap-on is on ground or work area, it is limited great to the wind-force passageway of wind-force water conservancy diversion, and the installation or dismantle all very loaded down with trivial details, reduce the practicality of water conservancy diversion structure, the water conservancy diversion structure needs to remove the regulation with the air pipe of whole wind field simultaneously, the operation is very complicated, and when the water conservancy diversion structure uses, wind-force directly blows on the water conservancy diversion structure, need use more transmission power just to promote the regulation of water conservancy diversion structure, the energy consumption is improved.

In view of this, it is necessary to develop a special guiding device for an intelligent wind farm.

Disclosure of Invention

The technical problem to be solved by the invention is to provide the special flow guide device for the intelligent wind field, the wind channel for wind flow guide is small in limitation, simple and convenient to install or disassemble and small in energy consumption, and the practicability of the flow guide structure can be effectively improved.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows:

a kind of intellectual wind field specialized guiding device, including 2 parallel bearing seats 1, several parallel slide rails 2 in sliding connection with 1 bottom of bearing seat, 2 wind field wind-collecting structures 3 set up in 2 bearing seats 1 upper ends separately, set up in 2 bearing seats 1 left can change the wind direction to carry on the diversion structure, wind-shielding buffer structure 6 and air cylinder 5 fixedly connected to one end of inboard side of bearing seat 1 of right side between 2 bearing seats 1; the cylinder 5 pushes the bearing seat 1 to move and adjust on the slide rail 2; when the diversion direction needs to be changed, the wind shielding buffer structure 6 can reduce the energy consumption of the diversion structure.

The technical scheme of the invention is further improved as follows: the wind field wind collecting structure comprises a flow guide screen, a fixed plate and a positioning bolt, wherein the flow guide screen is in sliding connection with the bearing seat, the fixed plate is fixedly connected with the bottom end of the flow guide screen and is in sliding connection with the bearing seat, and the positioning bolt is arranged on the inner side of the fixed plate and penetrates through the fixed plate and the bearing seat; the positioning bolt is connected with the bearing seat in a threaded mode and is connected with the fixing plate in a rotating mode.

The technical scheme of the invention is further improved as follows: the flow guide screen is of an arc-shaped plate structure, 2 flow guide screens are oppositely arranged, and a flow guide channel is formed in the middle of the flow guide screen.

The technical scheme of the invention is further improved as follows: : the flow guide structure can be arranged as a first flow guide structure or a second flow guide structure.

The technical scheme of the invention is further improved as follows: the first flow guide structure comprises a base, a fixed frame fixedly connected to the top end of the base, a first telescopic connecting rod fixedly connected to the bottom end of the outer side of the fixed frame, a flow guide plate rotatably connected to the inner side of the fixed frame, a rack fixedly connected to the top end of the outer side of the fixed frame, a first motor fixedly connected to the inner side of the rack, a driving bevel gear fixedly connected to the tail end of a main shaft of the first motor, and a driven bevel gear meshed with the outer side of the driving bevel gear;

two ends of the first telescopic connecting rod are fixedly connected with the 2 bearing seats; the driven bevel gear is fixedly connected with the guide plate so that the fixed frame is connected to the inner side of the bearing seat through the first telescopic connecting rod; the base is positioned and arranged at the middle position of the 2 bearing seats, the first motor drives the driving bevel gear to start rotating, and the guide plate is controlled to rotate by matching with the driven bevel gear.

The technical scheme of the invention is further improved as follows: the front side and the rear side of the guide plate are both provided with guide grooves; the whole guide plate is arranged in a triangular shape, and the right end of the guide plate is arranged in an arc shape.

The technical scheme of the invention is further improved as follows: the second flow guide structure comprises a wind collecting cover, a foot seat fixedly connected to the bottom end of the wind collecting cover, a positioning cylinder fixedly connected to the top end of the wind collecting cover, a second motor fixedly connected to the top end of the positioning cylinder, and a flow guide column fixedly connected to the tail end of a main shaft of the second motor;

a rubber ring layer for strengthening sealing is arranged on the outer side of the guide column, and the guide column is rotationally connected with the foot seat and the positioning cylinder so that the second motor can start working at the top end of the positioning cylinder to control the guide column at the tail end of the main shaft to rotate and adjust the position;

a through hole is formed in the middle of the inner side of the flow guide column; the rear side of the right end of the air collecting cover is provided with a first flow guide hole, the front side of the right end of the air collecting cover is provided with a second flow guide hole, the through hole which is convenient to rotate and adjust the middle position of the inner side of the flow guide column is in butt joint with the first flow guide hole or the second flow guide hole, and the flow direction of wind power is controlled.

The technical scheme of the invention is further improved as follows: : the wind shielding buffer structure comprises a base, second telescopic connecting rods fixedly connected to the front end and the rear end of the base, a hydraulic telescopic rod fixedly connected to the top end of the base, a connecting plate fixedly connected to the left end of the base, a support fixedly connected to the top end of the connecting plate, a rotating rod rotatably connected to the top end of the support and provided with a sliding groove in the inner side, a transmission shaft slidably connected to the inner side of the sliding groove of the rotating rod, the hydraulic telescopic rod rotatably connected with the transmission shaft and a wind shielding screen fixedly connected to the top end of the rotating rod;

the other end and 2 bearing seats fixed connection of second flexible connecting rod, the base is located the middle part position between 2 bearing seats.

The technical scheme of the invention is further improved as follows: the wind screen is arranged in an arc shape, so that the hydraulic telescopic rod can pull the transmission shaft to slide in the sliding groove of the rotating rod, and the rotating rod is pulled to rotate at the top end of the bracket to control the rotation of the wind screen; the rotation angle of the wind shield is 0-90 degrees.

The technical scheme of the invention is further improved as follows: the wind screen is made of polyethylene plates.

Due to the adoption of the technical scheme, the invention has the technical progress that:

1. this send out wind field collection wind structure and slide rail through being provided with the water conservancy diversion screen, the fixed plate, positioning bolt structure, this kind of sliding connection who sets up cooperation water conservancy diversion screen and bearing seat, the fixed plate is connected with positioning bolt's rotation and the sliding connection of slide rail and bearing seat, the staff places the bearing seat in the slide rail top, promote bearing seat via the cylinder and move on the slide rail and adjust, the water conservancy diversion screen can be fixed a position the fixed plate on bearing seat through using positioning bolt, it is less to be restricted, improve the practicality of water conservancy diversion structure.

2. The wind power guide device is provided with the first guide structure which is provided with the base, the fixing frame, the first motor, the guide plate and the like, the first guide structure is matched with the fixed connection of the base and the fixing frame, the fixed connection of the first motor and the driving bevel gear and the rotating connection of the guide plate and the fixing frame, the base is fixed at the middle position of the bearing seat, the first motor at the top end of the fixing frame drives the driving bevel gear at the tail end of the main shaft to drive the guide plate below the driven bevel gear at the outer side to rotate, and the guide groove at the outer side of the guide plate is matched to guide wind power, so that the operation is very simple.

3. According to the wind shielding buffer structure provided with the base, the hydraulic telescopic rod, the wind shielding screen, the rotating rod and the like, the wind shielding buffer structure is matched with the fixed connection of the base and the hydraulic telescopic rod, the fixed connection of the wind shielding screen and the rotating rod and the rotating connection of the support and the rotating rod, when the flow guide direction needs to be changed, the hydraulic telescopic rod at the top end of the base is started to contract, the hydraulic telescopic rod drives the transmission shaft to pull the rotating rod to rotate at the top end of the support to control the wind shielding screen to rotate to the right wind port of the flow guide screen, wind power is prevented from directly blowing to the flow guide plate, and the energy consumption of rotating the flow guide plate is reduced.

4. According to the invention, through the second flow guide structure provided with the structures such as the air collecting cover, the second motor, the flow guide column and the positioning cylinder, the arrangement is matched with the fixed connection of the air collecting cover and the foot seat, the fixed connection of the second motor and the positioning cylinder and the fixed connection of the second motor and the flow guide column, wind power is collected by the air collecting cover, and according to the flow guide requirement, the through hole on the flow guide column at the tail end of the second motor spindle at the top end of the positioning cylinder is controlled to be in butt joint with the first flow guide hole or the second flow guide hole, so that the flow guide direction of the intelligent wind field is changed.

5. The wind channel of the wind power diversion is small in limitation, simple and convenient to install or disassemble and low in energy consumption.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the mounting structure of the load bearing seat of the present invention;

FIG. 3 is a schematic view of the mounting structure of the first flow directing structure of the present invention;

FIG. 4 is a schematic view of the installation structure of the wind buffering structure of the present invention;

FIG. 5 is a schematic view of the mounting structure of a second flow directing structure of the present invention;

fig. 6 is a schematic view of an installation structure of the guide column of the present invention;

wherein: 1. the wind field wind collecting structure comprises a bearing seat, 2, a sliding rail, 3, a wind field wind collecting structure, 301, a diversion screen, 302, a fixing plate, 303, a positioning bolt, 4, a first diversion structure, 401, a base, 402, a fixing frame, 403, a first telescopic connecting rod, 404, a diversion plate, 405, a diversion trench, 406, a frame, 407, a first motor, 408, a driving bevel gear, 409, a driven bevel gear, 5, a cylinder, 6, a wind shielding buffer structure, 601, a base, 602, a second telescopic connecting rod, 603, a connecting plate, 604, a bracket, 605, a rotating rod, 606, a wind shielding screen, 607, a transmission shaft, 608, a hydraulic telescopic rod, 7, a positioning nail, 8, a balance plate, 9, a second diversion structure, 901, a wind collecting cover, 902, a foot seat, 903, a positioning cylinder, 904, a second motor, 905, a diversion column, 906, a through hole, 907, a first diversion hole, 908 and a second diversion hole.

Detailed Description

The invention is described in further detail below with reference to the following figures and examples:

in the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

Example 1

As shown in fig. 1, 2, 3 and 4, a special guiding device for an intelligent wind field comprises 2 bearing seats 1, the bottom ends of the bearing seats 1 are slidably connected with 2 equal sliding rails 2 (the sliding rails 2 are located at the lowest part of the whole device and support the bearing seats 1 to move), the top ends of the bearing seats 1 are provided with wind field wind collecting structures 3, each wind field wind collecting structure 3 comprises a guiding screen 301, the guiding screen 301 is slidably connected with the bearing seat 1, the bottom ends of the guiding screens 301 are fixedly connected with a fixing plate 302, the fixing plate 302 is slidably connected with the bearing seat 1, the inner sides of the fixing plates 302 are provided with positioning bolts 303, the positioning bolts 303 penetrate through the fixing plates 302 and the bearing seats 1, the positioning bolts 303 are spirally connected with the bearing seats 1, the positioning bolts 303 are rotatably connected with the fixing plates 302, the fixing plates 302 on the bearing seats 1 is facilitated by the positioning bolts 303, one ends of the inner sides of the bearing seats 1 are fixedly connected with cylinders 5, the inboard left of bearing seat 1 is equipped with first water conservancy diversion structure 4, and the right-hand buffer structure 6 that keeps out the wind that is equipped with of inboard of bearing seat 1, the left end fixedly connected with balance plate 8 of cylinder 5, the inboard screwed connection of balance plate 8 has location nail 7, is favorable to using location nail 7 to pass 8 fixed cylinder 5 of balance plate.

The flow guide screen 301 is positioned above the bearing seat 1 through the fixing plate 302 and along the bearing seat 1

The bearing seats are pushed outwards to move, and one opposite sides of the two bearing seats 1 are provided with T-shaped grooves;

the air cylinder 5 is fixed on one side of the bearing seat 1, one air cylinder 5 is connected with the two bearing seats 1 through a movable connecting rod, and the air cylinder 5 is directly fixed on the ground. The first flow guide structure 4 is integrally positioned above the bearing seat 1 and above the air cylinder 5, so that the installation is not influenced.

The first diversion structure 4 comprises a base 401, a fixed frame 402 is fixedly connected with the top end of the base 401, a first telescopic connecting rod 403 is fixedly connected with the bottom end of the outer side of the fixed frame 402, and the first telescopic connecting rod 403 is fixedly connected with the bearing seat 1, the inner side of the fixed frame 402 is rotatably connected with a guide plate 404, the top end of the outer side of the fixed frame 402 is fixedly connected with a frame 406, the inner side of the frame 406 is fixedly connected with a first motor 407, the tail end of a main shaft of the first motor 407 is fixedly connected with a driving bevel gear 408, the outer side of the driving bevel gear 408 is engaged with a driven bevel gear 409, and the driven bevel gear 409 is fixedly connected with the guide plate 404, so that the fixing frame 402 is conveniently connected to the outer side of the bearing seat 1 through the first telescopic connecting rod 403, the positioning base 401 is kept at the middle position of the bearing seat 1, the first motor 407 drives the driving bevel gear 408 to rotate, and the guide plate 404 is controlled to rotate by matching with the driven bevel gear 409; the front side and the rear side of the guide plate 404 are both provided with guide grooves 405, the guide plate 404 is arranged in a triangular shape, the right end of the guide plate 404 is arranged in an arc shape, wind power can be conveniently guided to wind direction through the guide grooves 405 on the front side and the rear side of the guide plate 404, and the triangular shape can better guide the wind direction; the first flow guiding structure 4 guides the wind direction by changing the angle of the flow guiding plate 404 and matching with the flow guiding groove 405.

The wind shielding buffer structure 6 comprises a base 601, wherein the front end and the rear end of the base 601 are fixedly connected with a second telescopic connecting rod 602, the other end of the second telescopic connecting rod 602 is fixedly connected with the bearing seat 1, the top end of the base 601 is fixedly connected with a hydraulic telescopic rod 608, so that the second telescopic connecting rods 602 on the two sides of the base 601 are conveniently connected to the outer side of the bearing seat 1, and the middle position of the base 601 is kept; the left end of the base 601 is fixedly connected with a connecting plate 603, the top end of the connecting plate 603 is fixedly connected with a support 604, the top end of the support 604 is rotatably connected with a rotating rod 605, a sliding groove is formed in the inner side of the rotating rod 605, a transmission shaft 607 is slidably connected to the inner side of the sliding groove of the rotating rod 605, the transmission shaft 607 is rotatably connected with a hydraulic telescopic rod 608, the top end of the rotating rod 605 is fixedly connected with a wind shield 606, the wind shield 606 is arranged in an arc shape, the hydraulic telescopic rod 608 can conveniently pull the transmission shaft 607 to slide in the sliding groove of the rotating rod 605, and therefore the rotating rod 605 is pulled to rotate at the top end of the support 604 to control the rotation of the wind shield 606; the rotation angle of the wind screen 606 is 0-90 degrees, and the wind screen 606 is made of polyethylene material, so that the production cost of the wind screen 606 made of polyethylene material is reduced.

The base 401 is directly placed above the cylinder 5 for installation, the base 601 is connected to one side of the bearing seat 1 through the second telescopic connecting rods 602 at the front side and the rear side, and the foot seat 902 is directly placed at any position between the two flow guide screens 301.

The number of the first telescopic connecting rods 403 and the number of the second telescopic connecting rods 602 are 2, the first telescopic connecting rods and the second telescopic connecting rods are respectively located on the front side and the rear side of the fixing frame 402 and the base 601, and the first telescopic connecting rods and the second telescopic connecting rods are fixedly connected to the bearing seat 1 through welding.

The working process is as follows: the device is powered by an external power supply, a worker places a bearing seat 1 above a sliding rail 2 in a butt joint manner, sequentially installs a first flow guide structure 4 and a wind shielding buffer structure 6 on the bearing seat 1 (a pulley or a guide structure can be arranged at the bottom end of the bearing seat 1 by self and positioned inside a sliding groove of the sliding rail 2, telescopic connections at two sides of an air cylinder 5 push the bearing seat 1 to move), switches on the power supply, starts the air cylinder 5, pushes the bearing seats 1 at two sides to move and open towards the front side and the back side above the sliding rail 2 by the air cylinder 5, a first telescopic connecting rod 403 at the outer side of a fixing frame 402 and a second telescopic connecting rod 602 at the front end and the back end of a base 601 are synchronously stretched and opened, a fixing plate 302 at the bottom end of a flow guide screen 301 in a wind field wind collecting structure 3 is clamped at the outer side of the bearing seat 1, the flow guide screen 301 is fixedly connected by using a positioning bolt 303, the installation is completed, and the wind field wind collecting structure 3 is butted to an intelligent wind field, wind power circulates with the first diversion structure 4 on the left side through the diversion screen 301, when the wind direction of a wind field needs to be changed, the hydraulic telescopic rod 608 above the base 601 of the wind shielding buffer structure 6 is started to work, the hydraulic telescopic rod 608 pulls the transmission shaft 607 at the top end to rotate, the transmission shaft 607 pulls the rotating rod 605 to rotate at the top end of the bracket 604, the rotating rod 605 drives the wind shielding screen 606 at the top end to synchronously rotate to the wind port at the right end of the diversion screen 301, wind is prevented from entering the wind field wind collecting structure 3, the first motor 407 in the rack 406 at the top end of the fixed frame 402 on the base 401 of the first diversion structure 4 is started, the first motor 407 drives the driving bevel gear 408 at the bottom end to rotate, the driving bevel gear 408 drives the driven bevel gear 409 engaged at the outer side to rotate, the driven bevel gear starts to drive the guide plate 404 below to rotate at the inner side of the fixed frame 402 by different angles, after the angle of the guide plate 404 is adjusted, the hydraulic telescopic rod 608 is started to push the transmission shaft 607 and the rotating rod 605 to start rotating to be in a vertical state, the rotating rod 605 rotates the wind shield 606 to the upper side of the guide screen 301 to start ventilation, and wind enters the wind field wind collecting structure 3 and moves from the guide groove 405 on the outer side of the guide plate 404 to the flow direction.

Example 2

As shown in fig. 5 and 6, parts of the special flow guide device for the intelligent wind farm which are the same as those in embodiment 1 are not described again, but the difference is that the first flow guide structure 4 is replaced by a second flow guide structure 9; the second flow guide structure 9 comprises a wind collection cover 901, a foot seat 902 is fixedly connected to the bottom end of the wind collection cover 901, a positioning cylinder 903 is fixedly connected to the top end of the wind collection cover 901, a second motor 904 is fixedly connected to the top end of the positioning cylinder 903, a flow guide column 905 is fixedly connected to the tail end of a main shaft of the second motor 904, a rubber ring layer is arranged on the outer side of the flow guide column 905, and the flow guide column 905 is rotatably connected with the foot seat 902 and the positioning cylinder 903, so that the second motor 904 starts to work at the top end of the positioning cylinder 903, the rotation and the position adjustment of the flow guide column 905 at the tail end of the main shaft are controlled, and the rubber ring layer on the outer side of the flow guide column 905 can enhance the sealing effect and avoid air leakage; a through hole 906 is formed in the middle of the inner side of the flow guide column 905, a first flow guide hole 907 is formed in the rear side of the right end of the air collection cover 901, a second flow guide hole 908 is formed in the front side of the right end of the air collection cover 901, the through hole 906 in the middle of the inner side of the flow guide column 905 can be conveniently adjusted in a rotating mode to be in butt joint with the first flow guide hole 907 or the second flow guide hole 908, and the flow direction of wind power is controlled. The second flow guiding structure 9 changes the wind direction by opening the through hole of the flow guiding column 905.

The working process is as follows: in embodiment 2, the same parts as those in embodiment 1 are not described again, except that the second flow guide structure 9 is moved to the left side of the wind field wind collecting mechanism 3 and pushed in, when flow guide is needed, the second motor 904 at different positions at the top end of the positioning cylinder 903 is started to operate, the second motor 904 drives the flow guide column 905 at the tail end of the main shaft to rotate in the wind collecting cover 901 and the foot seat 902, the through hole 906 in the middle position of the inner side of the flow guide column 905 is butted to the first flow guide hole 907 or the second flow guide hole 908, and wind power is controlled to be discharged from different wind ports.

The

above embodiments

1 and 2 can be simultaneously used according to the requirement of the intelligent wind field.

In summary, the invention arranges the bearing seat on the slide rail, the wind field wind collecting structure on the bearing seat, the flow guide structure and the wind shielding buffer structure between the bearing seats, and the cylinder at one end of the inner side of the bearing seat, the bearing seat is placed above the slide rail by a worker, the bearing seat is pushed by the cylinder to move and adjust on the slide rail, the flow guide screen can position the fixing plate on the bearing seat by using the positioning bolt, the limitation is small, the installation or the disassembly is simple and convenient, the energy consumption is small, and the practicability of the flow guide structure is improved.

Claims

1. The utility model provides a special guiding device of intelligence wind field which characterized in that: the wind power generation device comprises 2 parallel bearing seats (1), a plurality of parallel sliding rails (2) connected with the bottom ends of the bearing seats (1) in a sliding mode, 2 wind field wind collecting structures (3) respectively arranged at the upper ends of the 2 bearing seats (1), a flow guide structure arranged on the left side among the 2 bearing seats (1) and capable of changing the wind direction to guide the flow, a wind shielding buffer structure (6) arranged on the right side among the 2 bearing seats (1) and a cylinder (5) fixedly connected to one end of the inner side of the bearing seat (1); the cylinder (5) pushes the bearing seat (1) to move and adjust on the sliding rail (2); when the diversion direction needs to be changed, the wind shielding buffer structure (6) can reduce the energy consumption of the diversion structure.

2. The special guiding device of intelligence wind field of claim 1, characterized by: the wind field wind collecting structure (3) comprises a flow guide screen (301) connected with the bearing seat (1) in a sliding mode, a fixing plate (302) fixedly connected with the bottom end of the flow guide screen (301) and connected with the bearing seat (1) in a sliding mode, and a positioning bolt (303) arranged on the inner side of the fixing plate (302) and penetrating through the fixing plate (302) and the bearing seat (1); positioning bolt (303) and bearing seat (1) threaded connection, positioning bolt (303) and fixed plate (302) are rotated and are connected.

3. The special guiding device of intelligence wind field of claim 2, characterized by: the flow guide screen (301) is of an arc-shaped plate structure, 2 flow guide screens (301) are arranged oppositely, and a flow guide channel is formed in the middle.

4. The special guiding device of intelligence wind field of claim 1, characterized by: the flow guide structure can be arranged as a first flow guide structure (4) or a second flow guide structure (9).

5. The special guiding device of intelligence wind field of claim 4, characterized by: the first flow guide structure (4) comprises a base (401), a fixed frame (402) fixedly connected to the top end of the base (401), a first telescopic connecting rod (403) fixedly connected to the bottom end of the outer side of the fixed frame (402), a guide plate (404) rotatably connected to the inner side of the fixed frame (402), a rack (406) fixedly connected to the top end of the outer side of the fixed frame (402), a first motor (407) fixedly connected to the inner side of the rack (406), a driving bevel gear (408) fixedly connected to the tail end of a main shaft of the first motor (407), and a driven bevel gear (409) meshed with the outer side of the driving bevel gear (408);

two ends of the first telescopic connecting rod (403) are fixedly connected with 2 bearing seats (1); the driven bevel gear (409) is fixedly connected with the guide plate (404), so that the fixed frame (402) is connected to the inner sides of the 2 bearing seats (1) through the first telescopic connecting rod (403); the base (401) is positioned in the middle between the 2 bearing seats (1), the first motor (407) drives the driving bevel gear (408) to start rotating, and the guide plate (404) is controlled to rotate by matching with the driven bevel gear (409).

6. The special guiding device of intelligence wind field of claim 5, characterized by: guide grooves (405) are formed in the front side and the rear side of the guide plate (404); the whole guide plate (404) is arranged in a triangular shape, and the right end of the guide plate (404) is arranged in an arc shape.

7. The special guiding device of intelligence wind field of claim 4, characterized by: the second flow guide structure (9) comprises a wind collecting cover (901), a foot base (902) fixedly connected to the bottom end of the wind collecting cover (901), a positioning cylinder (903) fixedly connected to the top end of the wind collecting cover (901), a second motor (904) fixedly connected to the top end of the positioning cylinder (903), and a flow guide column (905) fixedly connected to the tail end of a main shaft of the second motor (904);

a rubber ring layer for reinforcing sealing is arranged on the outer side of the guide column (905), and the guide column (905) is rotatably connected with the foot seat (902) and the positioning barrel (903) so that the second motor (904) can start to work at the top end of the positioning barrel (903) to control the guide column (905) at the tail end of the main shaft to rotate and adjust the position;

a through hole (906) is formed in the middle of the inner side of the flow guide column (905); a first flow guide hole (907) is formed in the rear side of the right end of the air collecting cover (901), a second flow guide hole (908) is formed in the front side of the right end of the air collecting cover (901), a through hole (906) which is convenient to rotate and adjust the middle position of the inner side of the flow guide column (905) is connected to the first flow guide hole (907) or the second flow guide hole (908) in an abutting mode, and the flow direction of wind power is controlled.

8. The special guiding device of intelligence wind field of claim 1, characterized by: the wind shielding buffer structure (6) comprises a base (601), second telescopic connecting rods (602) fixedly connected to the front end and the rear end of the base (601), a hydraulic telescopic rod (608) fixedly connected to the top end of the base (601), a connecting plate (603) fixedly connected to the left end of the base (601), a support (604) fixedly connected to the top end of the connecting plate (603), a rotating rod (605) rotatably connected to the top end of the support (604) and provided with a sliding groove on the inner side, a transmission shaft (607) slidably connected to the inner side of the sliding groove of the rotating rod (605), the hydraulic telescopic rod (608) rotatably connected with the transmission shaft (607) and a wind shielding screen (606) fixedly connected to the top end of the rotating rod (605);

the other end and 2 bearing seats (1) fixed connection of second flexible connecting rod (602), base (601) are located the middle part position between 2 bearing seats (1).

9. The special guiding device of intelligence wind field of claim 8, characterized by: the wind screen (606) is arranged in an arc shape, so that the hydraulic telescopic rod (608) can pull the transmission shaft (607) to slide in the sliding groove of the rotating rod (605), and the rotating rod (605) is pulled to rotate at the top end of the support (604) to control the rotation of the wind screen (606); the rotation angle of the wind screen (606) is 0-90 degrees.

10. The special guiding device for the intelligent wind farm according to any one of the claims 8 or 9, wherein: the wind screen (606) is made of a polyethylene plate.