CN219492485U - Wind power monitoring device based on multidimensional sensor - Google Patents

Abstract

The utility model discloses a wind power monitoring device based on a multidimensional sensor, which comprises a bearing upright post fixedly arranged on the ground, wherein a conversion driving machine is fixedly arranged on the top surface of the bearing upright post; the front side and the rear side of the bearing upright post are fixedly provided with abutting type laths which are convenient to connect; further comprises: the right end of the conversion driving machine is rotatably provided with a wind power rotator through a bearing, and wind power blades are fixedly arranged on the outer wall of the wind power rotator at equal intervals; the outer wall of the right side of the top surface of the bearing upright post is connected with a sensor body in a sliding manner; the front side and the rear side of the top surface of the sensor body are both in sliding connection with current sensors for monitoring the work of the wind power rotator. This wind-powered electricity generation monitoring devices based on multidimensional sensor carries out the altitude mixture control of monitoring through installing in the sensor body that bears the stand outer wall to conduct real-time vision picture through signal transmitter through vision sensor appearance and current sensor appearance.

Description

Wind power monitoring device based on multidimensional sensor

Technical Field

The utility model relates to the technical field of wind power detection, in particular to a wind power monitoring device based on a multidimensional sensor.

Background

Wind power refers to wind power generation or short term of wind power generation, belongs to renewable energy and clean energy, and mostly adopts vertical wind power generation blades to realize power generation.

Publication number CN216117779U discloses a monitoring device for wind power running, a storage battery is electrically connected with a control switch, a current sensor and a signal transmitter, the side wall of the mounting frame is inserted with an adjusting bolt, the bottom end of the adjusting bolt is movably connected with a pushing plate through a bearing, the pushing plate is arc-shaped, and one side of the pushing plate is attached to the outer surface of the generator; according to the utility model, the wind power generation current can be monitored in real time, and when the generation current is abnormal, the remote monitoring system can know the abnormal situation in real time, so that the subsequent overhaul is convenient;

however, the above detection device has the following problems in the actual use process: install on corresponding wind power generation post through mounting bracket adjusting bolt, but can't independently realize detection such as not high wind speed through this detection device, its fixed mode leads to fog adaptability poor, leads to detecting false distance because of the back light of fog easily, or can't survey effective data because of thick fog leads to, and then leads to detecting data to have the deviation.

A wind power monitoring device based on a multi-dimensional sensor is proposed in order to solve the problems presented in the above.

Disclosure of Invention

The utility model aims to provide a wind power monitoring device based on a multidimensional sensor, which solves the problems that the prior art is provided that the wind power monitoring device is installed on a corresponding wind power generation column through a mounting frame adjusting bolt, but detection of wind speeds with different heights and the like cannot be realized independently through the detection device, the fog adaptability is poor due to a fixed mode, false distances are easily detected due to back light of fog, or effective data cannot be detected due to thick fog, and deviation exists in detection data.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the wind power monitoring device based on the multidimensional sensor comprises a bearing upright post fixedly installed on the ground, and a conversion driving machine is fixedly installed on the top surface of the bearing upright post;

the front side and the rear side of the bearing upright post are fixedly provided with abutting type laths which are convenient to connect, and the top surface of the conversion driving machine on the top surface of the bearing upright post is fixedly provided with a signal transmitter;

further comprises:

the right end of the conversion driving machine is rotatably provided with a wind power rotator through a bearing, and wind power blades are fixedly arranged on the outer wall of the wind power rotator at equal intervals;

the sensor body is slidably connected to the outer wall of the right side of the top surface of the bearing upright post, and visual sensors for monitoring the work of the wind power rotator are slidably connected to the front side and the rear side of the top surface of the sensor body;

the front side and the rear side of the top surface of the sensor body are both in sliding connection with current sensors for monitoring the work of the wind power rotator.

Preferably, the length between the outer wall conflict type lath of both sides around the stand that bears is less than the length of sensor body, and is concentric structure setting between sensor body and the stand that bears to both sides all are provided with the removal guide pulley through bearing rotation around the inner of sensor body, drive the sensor body through the removal guide pulley and go up and down.

Preferably, the sensor body is of an arc-shaped structure, the movable guide wheels at the front end and the rear end of the inner side of the sensor body are attached to the abutting type strip plates on the outer wall of the bearing upright post, the front side and the rear side of the inner end of the sensor body are attached to the outer wall of the abutting type strip plates in a sliding mode, and the sensor body is arranged on the outer wall of the bearing upright post through the abutting type strip plates.

Preferably, the inside outside of sensor body has seted up vision conduction spout, and the inside inboard of sensor body has seted up the electric current conduction spout to central point department between vision conduction spout and the electric current conduction spout is provided with drive gear through the bearing rotation, drives vision conduction slide and the inside work piece rotation of groove electric current conduction spout through drive guide pulley.

Preferably, the inside central point department of vision conduction spout is provided with the driving gear through the bearing rotation, and the inside front and back both sides of vision conduction spout all slide and are provided with driven rack to the driven rack meshing of front and back both sides is connected in the outer wall of driving gear, and the top surface of the driven rack of both sides all fixed connection in vision sensor's bottom in addition drives vision sensor through driven rack and removes.

Preferably, the driving gear inside the sensor body is meshed with the outer wall below the driving gear in the visual conduction chute, a guide rack is slidably arranged in the current conduction chute on the inner side of the sensor body, and guide tooth blocks are fixedly arranged on the inner wall of the current conduction chute on one side far away from the bearing upright post at equal intervals.

Preferably, the guide rack inside the current conduction chute is meshed and connected to the outer wall of the driving gear, the front side and the rear side of the top surface of the guide rack are respectively provided with the guide gear through bearing rotation, the guide gears on the front side and the rear side are meshed and connected to the guide tooth blocks on the inner wall of the current conduction chute, the guide gears on the front side and the rear side are respectively fixedly connected to the bottom end of the current sensor, and the current sensor is driven to rotate through rotation of the guide gears.

Compared with the prior art, the utility model has the beneficial effects that: this wind-powered electricity generation monitoring devices based on multidimensional sensor carries out the altitude mixture control of monitoring through installing in the sensor body that bears the stand outer wall to conduct real-time visual picture through signal transmitter through visual sensor appearance and current sensor appearance, its concrete content is as follows:

1. the sensor body is attached to the outer wall of the bearing upright post, the movable guide wheel is arranged on the inner side of the abutting-type strip plate on the outer wall of the bearing upright post, falling off is prevented in the monitoring process, the driving gear is driven by an external driving part to rotate, so that the driving gear drives the driving gear in the visual conduction chute to slide to two sides in the rotating process, the driven racks which are in meshed connection with the front side and the rear side are driven to slide to two sides, and the visual sensor fixedly connected with the top surface is driven by the driven racks to move, so that a real-time visual picture is conducted through the signal transmitter;

2. the drive gear drives the inside rack guide of electric current conduction spout to slide, and then makes its drive the guide gear of top surface rotate after the guide tooth piece of contact electric current conduction spout inner wall, and then drives the current sensor appearance of fixed connection in guide gear top surface and rotate to conduct through signal transmission ware equally, and then real-time supervision.

Drawings

FIG. 1 is a schematic diagram of the front structure of the present utility model;

FIG. 2 is a schematic view of a sensor body mounting structure according to the present utility model;

FIG. 3 is an enlarged schematic view of the structure of FIG. 2A according to the present utility model;

FIG. 4 is a schematic view of a sensor body according to the present utility model in a top-down cross-sectional configuration;

FIG. 5 is a schematic view of the mounting structure of the driving gear of the present utility model;

fig. 6 is an enlarged view of the structure of fig. 4B according to the present utility model.

In the figure: 1. a load-bearing upright; 2. converting a driving machine; 3. a butt-type slat; 4. a signal transmitter; 5. a wind power rotator; 6. wind power fan blades; 7. a sensor body; 8. a visual sensor; 9. a current sensor; 10. moving the guide wheel; 11. a visual conduction chute; 12. a current conducting chute; 13. a drive gear; 14. a drive gear; 15. a driven rack; 16. a guide rack; 17. a guide tooth block; 18. a guide gear.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, the present utility model provides the following technical solutions: the wind power monitoring device based on the multidimensional sensor comprises a bearing upright post 1 fixedly installed on the ground, and a conversion driving machine 2 is fixedly installed on the top surface of the bearing upright post 1; the front side and the rear side of the bearing upright post 1 are fixedly provided with a collision type slat 3 which is convenient to connect, the right end of the conversion driving machine 2 is rotatably provided with a wind power rotator 5 through a bearing, and the outer wall of the wind power rotator 5 is fixedly provided with wind power blades 6 at equal distance; as shown in fig. 1, the conversion driving machine 2 is firstly installed on the ground through a bearing upright post 1, then the wind power rotator 5 is used for equidistantly installing wind power fan blades 6, and the wind power rotator 5 is installed at the right end of the conversion driving machine 2, so that wind power in the external environment drives the wind power fan blades 6 and the wind power rotator 5 to rotate;

the top surface of the conversion driving machine 2 on the top surface of the bearing upright post 1 is fixedly provided with a signal transmitter 4; the right outer wall of the top surface of the bearing upright post 1 is slidably connected with a sensor body 7, and the front side and the rear side of the top surface of the sensor body 7 are slidably connected with a visual sensor 8 for monitoring the work of the wind power rotator 5; the front side and the rear side of the top surface of the sensor body 7 are both in sliding connection with a current sensor 9 for monitoring the work of the wind power rotator 5; as shown in fig. 1-2, the working state pictures and the current transmission efficiency of the wind power rotator 5 and the wind power fan blades 6 are monitored through a visual sensor 8 and a current sensor 9 respectively, and are transmitted in real time through a signal transmitter 4;

the front side and the rear side of the inner end of the sensor body 7 are respectively provided with a movable guide wheel 10 through bearings in a rotating way; the whole sensor body 7 is of an arc-shaped structure, the movable guide wheels 10 at the front end and the rear end of the inner side of the sensor body 7 are in fit connection with the abutting type lath 3 on the outer wall of the bearing upright post 1, and the front side and the rear side of the inner end of the sensor body 7 are in fit sliding connection with the outer wall of the abutting type lath 3; as shown in fig. 1-2, the sensor body 7 is mounted on the outer wall of the bearing upright column 1 in a bonding manner, and the movable guide wheels 10 at the front end and the rear end of the sensor body 7 are arranged on the inner side of the abutting-type slat 3 on the outer wall of the bearing upright column 1, so that falling-off is prevented in the monitoring process;

a visual conduction chute 11 is formed on the inner outer side of the sensor body 7, and a driving gear 13 is rotatably arranged at the central position between the visual conduction chute 11 and the current conduction chute 12 through a bearing; the driving gear 14 is rotatably arranged at the inner center position of the visual conduction chute 11 through a bearing, driven racks 15 are slidably arranged at the front side and the rear side of the inner part of the visual conduction chute 11, the driven racks 15 at the front side and the rear side are in meshed connection with the outer wall of the driving gear 14, and the top surfaces of the driven racks 15 at the front side and the rear side are fixedly connected with the bottom end of the visual sensor 8; as shown in fig. 4-5, the driving gear 13 at the central position inside the sensor body 7 is driven by an external driving component to rotate, so that the driving gear 13 drives the driving gear 14 inside the visual conduction chute 11 to slide to two sides in the process of rotating, and then the driven rack 15 which is in meshed connection with the front side and the rear side is driven to move, so that the visual sensor 8 which is fixedly connected with the top surface is driven by the driven rack 15 to move, and a real-time visual picture is conducted through the signal transmitter 4;

the inner side of the sensor body 7 is provided with a current conducting chute 12; the driving gear 13 inside the sensor body 7 is meshed with the outer wall below the driving gear 14 in the visual conduction chute 11, the guiding rack 16 is slidably arranged in the current conduction chute 12 inside the sensor body 7, and the guiding tooth blocks 17 are fixedly arranged on the inner wall of the current conduction chute 12 on one side far away from the bearing upright post 1 at equal distance; the guide rack 16 in the current conducting chute 12 is meshed with the outer wall of the driving gear 13, guide gears 18 are rotatably arranged on the front side and the rear side of the top surface of the guide rack 16 through bearings, the guide gears 18 on the front side and the rear side are meshed with guide tooth blocks 17 connected with the inner wall of the current conducting chute 12, and the guide gears 18 on the front side and the rear side are fixedly connected with the bottom end of the current sensor 9; as shown in fig. 4 and 6, the driving gear 13 drives the guiding rack 16 inside the current conducting chute 12 to slide, so that the guiding gear 18 on the top surface is driven to rotate after contacting the guiding tooth block 17 on the inner wall of the current conducting chute 12, and then the current sensor 9 fixedly connected to the top surface of the guiding gear 18 is driven to rotate, and is also conducted through the signal transmitter 4, so that real-time monitoring is performed.

Working principle: before the wind power monitoring device based on the multi-dimensional sensor is used, the whole situation of the device is required to be checked firstly, normal operation is ensured, wind power in the external environment drives wind power blades 6 and wind power rotators 5 to rotate according to the images shown in fig. 1-6, kinetic energy is converted into electric energy through a conversion driving machine 2, meanwhile, a sensor body 7 is attached to the outer wall of a bearing upright post 1, and movable guide wheels 10 at the front end and the rear end of the sensor body 7 are arranged on the inner sides of abutting type laths 3 on the outer wall of the bearing upright post 1, so that falling off in the monitoring process is prevented;

the driving gear 13 rotates under the drive of external driving components, the driving gear 14 drives the driven racks 15 which are in meshed connection with the front side and the rear side to slide to the two sides, the visual sensor 8 which drives the top surface to be fixedly connected moves, meanwhile, the driving gear 13 drives the guide rack 16 in the current conduction chute 12 to slide, the guide gear 18 which drives the top surface rotates after contacting the guide tooth block 17 on the inner wall of the current conduction chute 12, and the current sensor 9 which is fixedly connected to the top surface of the guide gear 18 drives to rotate, and is conducted through the signal transmitter 4, so that real-time monitoring is realized.

Although the present utility model has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present utility model.

Claims (7)

1. The wind power monitoring device based on the multidimensional sensor comprises a bearing upright post (1) fixedly installed on the ground, and a conversion driving machine (2) is fixedly installed on the top surface of the bearing upright post (1);

the front side and the rear side of the bearing upright post (1) are fixedly provided with abutting type battens (3) which are convenient to connect, and the top surface of the top surface conversion driving machine (2) of the bearing upright post (1) is fixedly provided with a signal transmitter (4);

characterized by further comprising:

the right end of the conversion driving machine (2) is rotatably provided with a wind power rotator (5) through a bearing, and wind power blades (6) are fixedly arranged on the outer wall of the wind power rotator (5) at equal intervals;

the right outer wall of the top surface of the bearing upright post (1) is slidably connected with a sensor body (7), and the front side and the rear side of the top surface of the sensor body (7) are slidably connected with visual sensors (8) for monitoring the work of the wind power rotator (5);

the front side and the rear side of the top surface of the sensor body (7) are both in sliding connection with a current sensor (9) for monitoring the work of the wind power rotator (5).

2. The multi-dimensional sensor-based wind power monitoring device of claim 1, wherein: the length between the outer wall conflict type lath (3) of both sides around bearing stand (1) is less than the length of sensor body (7), and is concentric structure setting between sensor body (7) and the bearing stand (1), and both sides all are provided with through the bearing rotation around the inner of sensor body (7) and remove guide pulley (10).

3. The multi-dimensional sensor-based wind power monitoring device of claim 1, wherein: the sensor body (7) is of an arc-shaped structure, the movable guide wheels (10) at the front end and the rear end of the inner side of the sensor body (7) are connected with the abutting type lath (3) of the outer wall of the bearing upright post (1) in a fitting mode, and the front side and the rear side of the inner end of the sensor body (7) are connected with the outer wall of the abutting type lath (3) in a fitting and sliding mode.

4. A multi-dimensional sensor based wind power monitoring device according to claim 3, wherein: the sensor is characterized in that a visual conduction chute (11) is formed in the outer side of the inner part of the sensor body (7), a current conduction chute (12) is formed in the inner side of the sensor body (7), and a driving gear (13) is rotatably arranged at the center position between the visual conduction chute (11) and the current conduction chute (12) through a bearing.

5. The multi-dimensional sensor-based wind power monitoring device of claim 4, wherein: the inside central point department of vision conduction spout (11) is provided with driving gear (14) through the bearing rotation, and both sides all slide around the inside of vision conduction spout (11) are provided with driven rack (15) to driven rack (15) meshing of both sides around are connected in the outer wall of driving gear (14), and the top surface of both sides driven rack (15) all fixed connection in the bottom of vision sensor appearance (8 around moreover.

6. The multi-dimensional sensor-based wind power monitoring device of claim 4, wherein: the inside drive gear (13) of sensor body (7) meshing is connected in the below outer wall of driving gear (14) in vision conduction spout (11), and slides in electric current conduction spout (12) of sensor body (7) inboard and be provided with guide rack (16), and the equidistant fixed mounting of inner wall that keeps away from one side of bearing column (1) of electric current conduction spout (12) has guide tooth piece (17).

7. The multi-dimensional sensor-based wind power monitoring device of claim 4, wherein: the inside guide rack (16) meshing of electric current conduction spout (12) is connected in the outer wall of drive gear (13), and both sides all are provided with guide gear (18) through the bearing rotation around the top surface of guide rack (16) to guide gear (18) meshing of both sides around are connected in guide tooth piece (17) of electric current conduction spout (12) inner wall, and guide gear (18) of both sides all fixed connection in electric current sensor appearance (9) bottom around moreover.