CN220435860U - Intelligent wind field operation and detection management device convenient to maintain - Google Patents

Abstract

The utility model relates to an intelligent wind field operation and detection management device convenient to maintain, which comprises a platform, wherein a lifting monitoring device is arranged at the top of the platform, the lifting monitoring device comprises a first hydraulic cylinder arranged at the top of the platform, and a fixed plate symmetrically arranged at the top of the platform, wherein one side of the fixed plate is symmetrically provided with a first sliding part, one side of the first sliding part is provided with a connecting plate, the other side of the connecting plate is provided with a second sliding part, the bottom of the connecting plate is provided with a lifting part, the top of the second sliding part is provided with a connecting block, and the top of the connecting block is provided with a monitoring part.

Description

Intelligent wind field operation and detection management device convenient to maintain

Technical Field

The utility model mainly relates to the technical field of wind field operation and detection, in particular to an intelligent wind field operation and detection management device convenient to maintain.

Background

The wind farm is composed of a wind generating set, a power transmission and transformation line, a wind power control system, a transformer substation, a booster station and the like.

In the existing wind field, a wind power control system is used for controlling a wind generating set to drive a windmill impeller to rotate by utilizing wind power to convert wind energy into a mechanical energy generator and then convert the mechanical energy into electric energy, the electric energy output by the wind generating set is transmitted to a transformer substation and a wind power field booster station through a current collecting circuit, and the electric energy is transmitted to a power grid after the booster station boosts the electric energy, wherein a data information collecting device for devices such as wind direction and wind speed monitoring of the wind field is transmitted to a PC (personal computer) for storage.

In the existing wind field, the data information collecting device for monitoring the wind direction, the wind speed and other devices in the wind field is transmitted to the PC for storage, but the device is inconvenient for monitoring the wind speed, the wind direction and the like in the wind field according to different heights.

Disclosure of Invention

The utility model mainly provides an intelligent wind field operation and detection management device convenient to maintain, which is used for solving the technical problems in the background technology.

The technical scheme adopted for solving the technical problems is as follows:

an intelligent wind field operation and inspection management device convenient to maintain comprises a platform, wherein a lifting monitoring device is arranged at the top of the platform;

the lifting monitoring device comprises a first hydraulic cylinder arranged at the top of the platform, and a fixing plate symmetrically arranged at the top of the platform, wherein one side of the fixing plate is provided with a first sliding part, one side of the first sliding part is provided with a connecting plate, the other side of the connecting plate is provided with a second sliding part, the bottom of the connecting plate is provided with a lifting part, the top of the second sliding part is provided with a connecting block, and the top of the connecting block is provided with a monitoring part.

Preferably, the first sliding component comprises a first sliding groove strip arranged on one side of the fixed plate, one side of a first sliding block is embedded in the first sliding groove strip, and the other side of the first sliding block is connected with one side of the connecting plate.

Preferably, the bottom of one end of the connecting plate is connected with the execution end of the first hydraulic cylinder.

Preferably, the second sliding part comprises a second sliding groove strip arranged on the other side of the connecting plate, a second sliding block is embedded in the second sliding groove strip, and a seven-shaped plate is arranged on one side of the second sliding block.

Preferably, the connecting block is arranged at the top of the seven-shaped plate.

Preferably, the monitoring component comprises an ultrasonic anemoscope which is arranged at the top of the connecting block and is magnetically attracted.

Preferably, the lifting component comprises a second hydraulic cylinder arranged at the bottom of the other side of the connecting plate, and the execution end of the second hydraulic cylinder is connected with the bottom of the connecting block.

Compared with the prior art, the utility model has the beneficial effects that:

the wind speed and direction monitoring device is convenient for monitoring wind speed and direction and the like according to different heights in a wind field.

According to the utility model, the wind field is monitored through the lifting monitoring device, so that the monitoring component can be lifted and monitored according to different heights, and the omnibearing monitoring of the wind direction, humidity, temperature and other factors of the wind field can be conveniently monitored through the monitoring component.

The utility model will be explained in detail below with reference to the drawings and specific embodiments.

Drawings

FIG. 1 is an isometric view of the overall structure of the present utility model;

FIG. 2 is an isometric view of a lift monitoring device of the present utility model;

FIG. 3 is a cross-sectional view of the overall structure of the present utility model;

fig. 4 is a bottom view of the ultrasonic anemometer of the present utility model.

Description of the drawings: 10. a platform; 20. a lifting monitoring device; 21. a first hydraulic cylinder; 22. a fixing plate; 23. a first sliding member; 231. a first chute bar; 232. a first slider; 24. a connecting plate; 25. a second sliding member; 251. the second chute bar; 252. a second slider; 253. seven-character board; 26. a lifting member; 261. a second hydraulic cylinder; 27. a connecting block; 28. a monitoring component; 281. ultrasonic anemoclinographs.

Detailed Description

In order that the utility model may be more fully understood, a more particular description of the utility model will be rendered by reference to the appended drawings, in which several embodiments of the utility model are illustrated, but which may be embodied in different forms and are not limited to the embodiments described herein, which are, on the contrary, provided to provide a more thorough and complete disclosure of the utility model.

It will be understood that when an element is referred to as being "mounted" on another element, it can be directly on the other element or intervening elements may be present, and when an element is referred to as being "connected" to the other element, it may be directly connected to the other element or intervening elements may also be present, the terms "vertical", "horizontal", "left", "right" and the like are used herein for the purpose of illustration only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs, and the terms used herein in this description of the utility model are for the purpose of describing particular embodiments only and are not intended to be limiting of the utility model, with the term "and/or" as used herein including any and all combinations of one or more of the associated listed items.

Referring to fig. 1, 3 and 4, in a preferred embodiment of the present utility model, an intelligent wind farm operation and inspection management device convenient for maintenance includes a platform 10, a lifting monitoring device 20 is disposed on top of the platform 10, a monitoring component 28 is disposed on top of the connecting block 27, and the monitoring component 28 includes an ultrasonic anemometer 281 disposed on top of the connecting block 27 and magnetically attracted.

It should be noted that, in this embodiment, when the wind field needs to be monitored, the ultrasonic anemometer 281 is placed in the groove on the connecting block 27, at this time, the ultrasonic anemometer 281 and the connecting block 27 are fixed by magnetic attraction, so that the disassembly and the installation are convenient, and other monitoring devices can be installed, meanwhile, the wind direction of the wind field is measured by the ultrasonic waves through the four ultrasonic sensors on the ultrasonic anemometer 281, the ultrasonic waves are sent and received in a two-dimensional plane in a circulating way through the ultrasonic waves, and the time difference of the ultrasonic waves propagating in the air is used for measuring the wind speed and the wind direction, even breeze can be measured, 360-degree azimuth monitoring can be performed, and the measured data are transmitted to the PLC controller, so that remote monitoring and transmission can be realized, the wind direction of the wind field can be monitored conveniently and rapidly, and the solar panel can be also be set for energy storage and power supply.

Referring to fig. 1, 2, 3, and 4, the lifting monitoring device 20 includes a first hydraulic cylinder 21 disposed at the top of the platform 10, and a fixed plate 22 disposed at the top of the platform 10, wherein the fixed plate 22 is disposed symmetrically, one side of the fixed plate 22 is provided with a first sliding member 23, one side of the first sliding member 23 is provided with a connecting plate 24, the other side of the connecting plate 24 is provided with a second sliding member 25, and the bottom is provided with a lifting member 26, the top of the second sliding member 25 is provided with a connecting block 27, the top of the connecting block 27 is provided with a monitoring member 28, the first sliding member 23 includes a first sliding groove strip 231 disposed at one side of the fixed plate 22, the other side of the first sliding block 232 is connected with one side of the connecting plate 24, one end bottom of the connecting plate 24 is connected with an executing end of the first hydraulic cylinder 21, the second sliding member 25 includes a second sliding groove strip 251 disposed at the other side of the connecting plate 24, the second sliding member 251 is embedded with a second sliding member 252, one side of the second sliding member 252 is provided with a seven-shaped sliding bar 253, the seven-shaped sliding member 253 is disposed at the other side of the connecting plate 27, the bottom of the connecting block 27 includes a magnetic force-absorbing member 261 disposed at the bottom of the connecting block 27, and the bottom of the connecting block 27 is disposed at the bottom of the connecting block 27.

It should be noted that, in this embodiment, when the wind field needs to be monitored according to different heights, the first hydraulic cylinder 21 is triggered by the PLC controller to drive the connecting plate 24 to slide upwards in the first chute bar 231 through the first sliding blocks 232 on both sides of the fixing plate 22, and at this time, the ultrasonic anemometer 281 on the connecting block 27 at the top of the connecting plate 24 is lifted simultaneously, so that the wind field is monitored by the ultrasonic anemometer 281, the second hydraulic cylinder 261 is triggered by the PLC controller to drive the ultrasonic anemometer 281 on the connecting block 27 connected with the seven-shaped plate 253 to slide upwards in the second chute bar 251 through the second sliding blocks 252, so that the ultrasonic anemometer 281 is lifted again, and the monitoring on the higher position of the wind field is facilitated.

Referring to fig. 1, 2, 3, and 4, the lifting monitoring device 20 includes a first hydraulic cylinder 21 disposed at the top of the platform 10, and a fixed plate 22 disposed at the top of the platform 10, wherein the fixed plate 22 is disposed symmetrically, one side of the fixed plate 22 is provided with a first sliding member 23, one side of the first sliding member 23 is provided with a connecting plate 24, the other side of the connecting plate 24 is provided with a second sliding member 25, and the bottom is provided with a lifting member 26, the top of the second sliding member 25 is provided with a connecting block 27, the top of the connecting block 27 is provided with a monitoring member 28, the first sliding member 23 includes a first sliding groove strip 231 disposed at one side of the fixed plate 22, the other side of the first sliding block 232 is connected with one side of the connecting plate 24, one end bottom of the connecting plate 24 is connected with an executing end of the first hydraulic cylinder 21, the second sliding member 25 includes a second sliding groove strip 251 disposed at the other side of the connecting plate 24, the second sliding member 251 is embedded with a second sliding member 252, one side of the second sliding member 252 is provided with a seven-shaped sliding bar 253, the seven-shaped sliding member 253 is disposed at the other side of the connecting plate 27, the bottom of the connecting block 27 includes a magnetic force-absorbing member 261 disposed at the bottom of the connecting block 27, and the bottom of the connecting block 27 is disposed at the bottom of the connecting block 27.

It should be noted that, in this embodiment, when the device needs to be lowered, the second hydraulic cylinder 261 is triggered by the PLC controller to drive the ultrasonic anemoscope 281 on the connection block 27 connected with the seven-shaped plate 253 to slide down in the second sliding groove strip 251 through the second sliding block 252, the first hydraulic cylinder 21 is triggered by the PLC controller to drive the connection plate 24 to slide down in the first sliding groove strip 231 through the first sliding blocks 232 on both sides of the fixed plate 22, at this time, the ultrasonic anemoscope 281 on the connection block 27 on the top of the connection plate 24 is lowered simultaneously, so that the ultrasonic anemoscope 281 is lowered to the bottom, and monitoring of different heights and different time periods can be performed simultaneously during the lifting process of the ultrasonic anemoscope 281, so as to facilitate maintenance of the staff, wherein the device housing and the fixed plate 22, the connection plate 24, the seven-shaped plate 253, the first sliding groove strip 231, the second sliding groove strip 251, the connection block 27 and the like in the lifting monitoring device 20 are also detachable, so that the staff can maintain and overhaul the inside.

The specific flow of the utility model is as follows:

the model of the PLC is 'AP-120 BR', and the model of the ultrasonic sensor is 'SU 18R-M1 MN-F'.

Firstly, when the wind field needs to be monitored, the ultrasonic anemometer 281 is placed in a groove on the connecting block 27, at the moment, the ultrasonic anemometer 281 and the connecting block 27 are fixed through magnetic attraction, so that the maintenance is convenient for workers, other monitoring devices can be installed, four ultrasonic sensors on the ultrasonic anemometer 281 are far away from the wind direction of the measured wind speed through ultrasonic waves, the four ultrasonic probes circularly send and receive ultrasonic waves in a two-dimensional plane, the time difference of the ultrasonic waves transmitted in the air is used for measuring the wind speed and the wind direction, even breeze can be measured, meanwhile, 360-degree azimuth monitoring can be performed, the temperature, the humidity, the noise, the atmospheric pressure and the like in the air can be monitored, the measured data are transmitted to a PLC controller, remote monitoring and transmission can be realized, the wind speed and the wind direction of the wind field can be conveniently and rapidly monitored, and a solar panel can be set for energy storage and power supply.

Secondly, when wind fields are required to be monitored according to different heights, the first hydraulic cylinder 21 is triggered by the PLC controller to drive the connecting plate 24 to slide upwards in the first chute bar 231 through the first sliding blocks 232 on two sides of the fixed plate 22, at the moment, the ultrasonic anemometers 281 on the connecting block 27 at the top of the connecting plate 24 are lifted simultaneously, so that wind field monitoring is carried out through the ultrasonic anemometers 281, the second hydraulic cylinder 261 is triggered by the PLC controller to drive the ultrasonic anemometers 281 on the connecting block 27 connected with the seven-shaped plate 253 to slide upwards in the second chute bar 251 through the second sliding blocks 252, and accordingly the ultrasonic anemometers 281 are lifted again, and monitoring on the higher positions of the wind fields is facilitated.

Finally, when the ultrasonic anemometer 281 on the connecting block 27 connected with the seven-shaped plate 253 is triggered by the PLC controller to slide downwards in the second sliding groove strip 251 through the second sliding block 252, the connecting plate 24 is triggered by the PLC controller to slide downwards in the first sliding groove strip 231 through the first sliding blocks 232 on two sides of the fixed plate 22 through the first hydraulic cylinder 21, at the moment, the ultrasonic anemometer 281 on the connecting block 27 on the top of the connecting plate 24 simultaneously descends downwards, so that the ultrasonic anemometer 281 descends to the bottom, and monitoring of different heights and different time periods can be performed simultaneously in the ascending and descending process of the ultrasonic anemometer 281, thereby facilitating maintenance of staff, wherein the device shell and the fixed plates 22, the connecting plate 24, the seven-shaped plate 253, the first sliding groove strip 231, the second sliding groove strip 251, the connecting block 27 and the like in the ascending and descending monitoring device 20 are also detachable, and facilitating internal maintenance and overhaul of staff.

While the utility model has been described above with reference to the accompanying drawings, it will be apparent that the utility model is not limited to the embodiments described above, but is intended to be within the scope of the utility model, as long as such insubstantial modifications are made by the method concepts and technical solutions of the utility model, or the concepts and technical solutions of the utility model are applied directly to other occasions without any modifications.

Claims (7)

1. An intelligent wind farm operation and inspection management device convenient to maintain comprises a platform (10), and is characterized in that a lifting monitoring device (20) is arranged at the top of the platform (10);

lifting monitoring devices (20) are including locating first pneumatic cylinder (21) at platform (10) top, and the symmetry is located fixed plate (22) at platform (10) top, the symmetry is equipped with fixed plate (22) one side all is equipped with first sliding part (23), first sliding part (23) one side is equipped with connecting plate (24), connecting plate (24) opposite side is equipped with second sliding part (25), and the bottom is equipped with lifting part (26), second sliding part (25) top is equipped with connecting block (27), connecting block (27) top is equipped with monitoring part (28).

2. The intelligent wind farm operation and inspection management device convenient to maintain according to claim 1, wherein the first sliding component (23) comprises a first sliding groove strip (231) arranged on one side of the fixed plate (22), one side of a first sliding block (232) is embedded in the first sliding groove strip (231), and the other side of the first sliding block (232) is connected with one side of the connecting plate (24).

3. The intelligent wind farm operation and inspection management device convenient to maintain according to claim 1, wherein one end bottom of the connecting plate (24) is connected with the execution end of the first hydraulic cylinder (21).

4. The intelligent wind farm operation and inspection management device convenient to maintain according to claim 1, wherein the second sliding component (25) comprises a second sliding groove strip (251) arranged on the other side of the connecting plate (24), a second sliding block (252) is embedded in the second sliding groove strip (251), and a seven-shaped plate (253) is arranged on one side of the second sliding block (252).

5. The intelligent wind farm operation and inspection management device convenient to maintain according to claim 4, wherein the connecting block (27) is arranged at the top of the seven-shaped plate (253).

6. The intelligent wind farm operation and inspection management device convenient to maintain according to claim 1, wherein the monitoring component (28) comprises an ultrasonic anemoscope (281) which is arranged at the top of the connecting block (27) and is magnetically attracted.

7. The intelligent wind farm operation and inspection management device convenient to maintain according to claim 1, wherein the lifting component (26) comprises a second hydraulic cylinder (261) arranged at the bottom of the other side of the connecting plate (24), and an execution end of the second hydraulic cylinder (261) is connected with the bottom of the connecting block (27).