CN113417811A

CN113417811A - Wind power monitoring device

Info

Publication number: CN113417811A
Application number: CN202110870964.1A
Authority: CN
Inventors: 杨洪波; 刘鸿国; 苏江卉; 潘显亮; 王智英
Original assignee: Fujian Jinjiang Cogeneration Co ltd; CHN Energy Group Fujian Energy Co Ltd
Current assignee: Fujian Jinjiang Cogeneration Co ltd; CHN Energy Group Fujian Energy Co Ltd
Priority date: 2021-07-30
Filing date: 2021-07-30
Publication date: 2021-09-21

Abstract

The application discloses wind power monitoring equipment relates to wind power generation technical field. The wind power monitoring equipment comprises a shell, a cover body, a wind power monitoring assembly and a first lifting mechanism, wherein the cover body can be arranged on the shell in an opening and closing mode, the first lifting mechanism is arranged in the shell, the wind power monitoring assembly is arranged on the first lifting mechanism, and under the condition that the cover body is in an opening state, the first lifting mechanism can drive the wind power monitoring assembly to extend out of the shell or retract into the shell. According to the wind power monitoring device, the problem that in the related art, the wind power monitoring device is directly exposed to the outside, so that the wind power monitoring device is easy to damage can be solved.

Description

Wind power monitoring device

Technical Field

The application belongs to the technical field of wind power generation, and particularly relates to a wind power monitoring device.

Background

Wind power generation converts wind energy into electric energy, is very environment-friendly, and has huge wind energy storage amount, so that the wind power generation is more and more valued by people.

When wind power generation equipment works, wind power generally needs to be monitored, and the existing wind power monitoring equipment is directly exposed to the outside, so that related parts of the wind power monitoring equipment cannot be protected, and the wind power monitoring equipment is easy to damage when the weather condition is severe.

Disclosure of Invention

The embodiment of the application aims to provide a wind power monitoring device, and the problem that in the related art, the wind power monitoring device is directly exposed to the outside, so that the wind power monitoring device is easily damaged can be solved.

In order to solve the technical problem, the present application is implemented as follows:

the embodiment of the application provides a wind power monitoring equipment, including casing, lid, wind power monitoring subassembly and first elevating system, wherein: the cover body can be arranged in the shell in an opening and closing mode, the first lifting mechanism is arranged in the shell, the wind power monitoring assembly is arranged in the first lifting mechanism, and under the condition that the cover body is in an opening state, the first lifting mechanism can drive the wind power monitoring assembly to extend out of the shell or retract into the shell.

In this application embodiment, the casing can be located to the lid with opening and shutting, the casing is located through first elevating system liftable to wind-force monitoring subassembly, under the condition that needs carry out wind-force monitoring, open the lid, first elevating system drive wind-force monitoring subassembly stretches out outside the casing, realize the purpose of wind-force monitoring, under the condition that needs protect wind-force monitoring subassembly, first elevating system drive wind-force monitoring subassembly retracts back to in the casing, close the lid, lid and casing enclose into enclosure space, wind-force monitoring subassembly is located enclosure space, realize the purpose of protection wind-force monitoring subassembly. Therefore, the problem that in the related art, the wind power monitoring equipment is directly exposed to the outside, so that the wind power monitoring equipment is easily damaged can be solved.

Drawings

FIG. 1 is a schematic external view of a wind monitoring device according to an embodiment of the present disclosure;

FIG. 2 is a schematic view of an internal structure of a wind monitoring device according to an embodiment of the present disclosure;

FIG. 3 is a schematic structural diagram of an opening and closing assembly disclosed in an embodiment of the present application;

fig. 4 is a schematic internal structural diagram of a control box disclosed in an embodiment of the present application.

Description of reference numerals:

100-shell body,

200-cover body, 210-first cover, 220-second cover,

300-a first lifting mechanism, 310-a support, 320-a screw, 330-a second power device, 340-a guide,

400-an opening and closing component, 410-a first connecting rod, 420-a second connecting rod, 430-a third connecting rod, 440-a fourth connecting rod, 450-a first fixing piece, 460-a second fixing piece, 470-a connecting piece, 480-a first power device,

500-a second lifting mechanism,

610-wind speed detection element, 620-wind direction detection element, 621-wind direction auxiliary plate,

710-controller, 720-signal receiver, 730-signal transmitter, 740-control box,

800-fixing the rod.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some, but not all, embodiments of the present application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The terms first, second and the like in the description and in the claims of the present application are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It will be appreciated that the data so used may be interchanged under appropriate circumstances such that embodiments of the application may be practiced in sequences other than those illustrated or described herein, and that the terms "first," "second," and the like are generally used herein in a generic sense and do not limit the number of terms, e.g., the first term can be one or more than one.

The embodiments of the present application are described in detail below with reference to the accompanying drawings through specific embodiments and application scenarios thereof.

Referring to fig. 1 to 4, an embodiment of the present application discloses a wind power monitoring apparatus, which includes a housing 100, a cover 200, a wind power monitoring assembly, and a first lifting mechanism 300.

The cover 200 is openably and closably provided in the housing 100. Alternatively, the cover 200 may be rotatably connected to the housing 100 by a hinge shaft or the like, or may be connected to the housing 100 in a snap-fit manner. The first lifting mechanism 300 is disposed in the housing 100, the wind monitoring assembly is disposed in the first lifting mechanism 300, and when the cover 200 is in the open state, the first lifting mechanism 300 can drive the wind monitoring assembly to extend out of the housing 100, and the first lifting mechanism 300 can also drive the wind monitoring assembly to retract into the housing 100.

In the embodiment of the application, when wind power monitoring is required, the cover 200 is opened, the first lifting mechanism 300 drives the wind power monitoring assembly to extend out of the casing 100, so that the purpose of wind power monitoring is achieved, when the wind power monitoring assembly is required to be protected, the first lifting mechanism 300 drives the wind power monitoring assembly to retract into the casing 100, the cover 200 is closed, a closed space is defined by the cover 200 and the casing 100, and the wind power monitoring assembly is located in the closed space, so that the purpose of protecting the wind power monitoring assembly is achieved. Therefore, the problem that in the related art, the wind power monitoring equipment is directly exposed to the outside, so that the wind power monitoring equipment is easily damaged can be solved.

In order to realize the opening and closing of the cover 200, the wind monitoring device may further include an opening and closing assembly 400, the opening and closing assembly 400 may include a first connecting rod 410 and a second connecting rod 420, the first connecting rod 410 may be hinged to the second connecting rod 420 through a connecting member 470, and the other end of the first connecting rod 410 may be hinged to the housing 100, and the other end of the second connecting rod 420 may be hinged to the cover 200, so that the first connecting rod 410 rotates to sequentially drive the second connecting rod 420 and the cover 200 to rotate, so as to switch the cover 200 between the open state and the closed state. Alternatively, the connecting member 470 may be a hinge shaft. Under the circumstance, the opening and closing of the cover body 200 can be realized through the opening and closing assembly 400, and under the circumstance that the cover body 200 is in the opening state, the first connecting rod 410 and the second connecting rod 420 can support the cover body 200, thereby ensuring the stability of the cover body 200 and preventing the cover body 200 from shaking under the action of wind power.

In a further embodiment, the opening and closing assembly 400 may further include a third connecting rod 430 and a fourth connecting rod 440, the third connecting rod 430 and the fourth connecting rod 440 may be hinged by a connecting member 470, and the other end of the third connecting rod 430 may be hinged to the case 100, the other end of the fourth connecting rod 440 may be hinged to the cover 200, and the third connecting rod 430 may be hinged to the second connecting rod 420 by the connecting member 470. Optionally, the third connecting rod 430 may be a bent rod, so as to conveniently drive the cover 200 to move. Thus, when the second connecting rod 420 rotates, the second connecting rod 420 rotates to sequentially drive the third connecting rod 430, the fourth connecting rod 440 and the cover 200 to rotate. In this case, the third connecting rod 430 and the fourth connecting rod 440 can also support the cover body 200, and the combination of the first connecting rod 410 and the second connecting rod 420 can provide a greater supporting force for the cover body 200, so that the cover body 200 is more stable and can be kept stable under the action of greater wind.

In an alternative embodiment, the cover 200 may include a first cover 210 and a second cover 220, the number of the opening and closing assemblies 400 may be two, and the two opening and closing assemblies 400 are respectively connected to the first cover 210 and the second cover 220. In this case, the two opening/closing assemblies 400 are used to support the first cover 210 and the second cover 220, respectively, so that the support strength of the first cover 210 and the second cover 220 can be increased, and the stability of the cover body 200 can be further ensured.

In the above-mentioned scheme, the first connecting rod 410 and the third connecting rod 430 may be both hinged to the case 100, and the second connecting rod 420 and the fourth connecting rod 440 may be both hinged to the cover body 200, but the installation process of directly hinging to the cover body 200 or the case 100 is difficult. For this, the inner wall of the case 100 may be provided with a first fixing member 450, the first connecting rod 410 and the third connecting rod 430 may be hinged to the first fixing member 450 by a connecting member 470, the inner wall of the cover 200 may be provided with a second fixing member 460, and the second connecting rod 420 and the fourth connecting rod 440 may be hinged to the second fixing member 460 by a connecting member 470. In this case, the installation difficulty is reduced, and the installation of the first connecting rod 410, the second connecting rod 420, the third connecting rod 430 and the fourth connecting rod 440 is facilitated.

In the above scheme, it can be seen that the cover body 200 is opened and closed depending on the rotation of the first connection rod 410, and there are various ways for rotating the first connection rod 410, for example, a handwheel may be disposed on the housing 100, a portion of the handwheel extends into the housing 100 and is connected to the first connection rod 410 through a transmission mechanism such as a gear pair, and the first connection rod 410 can be driven to rotate by the rotation of the gear pair.

However, the above method requires manual work and is time-consuming and labor-consuming. To this end, the opening and closing assembly 400 may further include a first power device 480, and the first connecting rod 410 may be connected to the first power device 480, and the first power device 480 may be used to drive the first connecting rod 410 to rotate. Alternatively, the first power device 480 may be a first motor, and the first connecting rod 410 may be connected to an output shaft of the first motor. In this case, the first power device 480 is used to automatically rotate the first connecting rod 410, thereby saving labor.

The specific structure of the first lifting mechanism 300 may be various, for example, the first lifting mechanism 300 may be an electric telescopic rod, and the specific structure of the first lifting mechanism 300 is not limited herein as long as the wind power monitoring assembly can be driven to move.

In an alternative embodiment, the first lifting mechanism 300 may include a support 310, a screw 320, and a second power device 330, the wind monitoring assembly may be disposed on the support 310, the support 310 may be threadedly coupled to the screw 320, the screw 320 may be coupled to the second power device 330, and the second power device 330 is configured to drive the screw 320 to rotate, and the rotation of the screw 320 may drive the support 310 and the wind monitoring assembly to move. Alternatively, the support member 310 may be a support plate, and the surface of the support plate facing the cover body 200 is parallel to the horizontal plane to ensure the stability of the wind monitoring assembly. Alternatively, the second power device 330 may be a second motor, and the screw 320 may be connected to an output shaft of the second motor. Alternatively, the thread structure of the support member 310 may be disposed on the side wall of the support member 310, the support member 310 may also be provided with a complete threaded hole, the threaded hole may be disposed at the middle position or near the edge of the support member 310, and the screw 320 is engaged with the threaded hole. Under the condition, the second power device 330 is turned on, the second power device 330 drives the screw 320 to rotate, and the support member 310 moves along the extending direction of the screw 320 under the action of the thread structure, so that the support member 310 is lifted, and the wind power monitoring assembly is lifted.

In order to improve the moving accuracy of the support member 310, the first lifting mechanism 300 may further include a guide 340, the guide 340 may be disposed in the housing 100, the support member 310 may be provided with a guide structure, and the guide 340 and the guide structure may be guided to cooperate in the moving direction of the support member 310. Alternatively, the guide 340 may be a sliding rod, and the guide structure may be a through hole formed in the support 310, through which the sliding rod passes. In this case, the guide 340 guides the movement of the support 310, and thus, the movement of the support 310 can be prevented from being deviated.

In an alternative embodiment, the supporting member 310 may be a supporting plate, the number of the guiding members 340 may be 3, the screw 320 is located near one of the corners of the supporting plate, and the 3 guiding members 340 are respectively disposed at the remaining three corners of the supporting plate.

In order to further adjust the height of the wind power monitoring assembly, the wind power monitoring apparatus may further include a second lifting mechanism 500, the second lifting mechanism 500 may be disposed on the support member 310, so that the support member 310 drives the second lifting mechanism 500 to move, the wind power monitoring assembly may be disposed on the second lifting mechanism 500, and the second lifting mechanism 500 drives the wind power monitoring assembly to move. Optionally, the second lifting mechanism 500 may be an air cylinder, a cylinder body of the air cylinder is connected with the support member 310, a lever of the air cylinder is connected with the wind power monitoring assembly, in the case that the second lifting mechanism 500 is an air cylinder, the lever of the air cylinder may be connected with the fixing rod 800, and the wind power monitoring assembly may be disposed on the fixing rod 800. Under this kind of circumstances, the protractile length of wind-force monitoring subassembly has further been lengthened, and then has increased the height-adjustable scope of wind-force monitoring subassembly for wind-force monitoring subassembly can monitor the wind of co-altitude not as required, guarantees that the data monitored are more accurate.

The wind power monitoring assembly comprises a wind speed detecting element 610, a wind direction detecting element 620 and a wind direction auxiliary plate 621, wherein one end of the wind direction auxiliary plate 621 is movably hung on the wind direction detecting element 620, and the wind direction auxiliary plate 621 can rotate relative to the wind direction detecting assembly under the action of wind power. Alternatively, the wind speed detecting element 610 may be a wind speed sensor. Alternatively, the wind direction detecting element 620 may be a wind direction sensor. Alternatively, one end of the wind direction auxiliary plate 621 may be connected to the wind direction detecting element 620 through a suspension ring. In this case, the wind blows on the wind direction auxiliary plate 621, and the area of the wind direction auxiliary plate 621 is large, so that the area blocked by the wind is large, the wind direction sensor is easy to move, and the direction of the wind can be detected more quickly.

In a further aspect, the wind monitoring apparatus may further include a controller 710, a signal receiver 720, and a signal transmitter 730. Wherein the wind monitoring assembly is communicatively coupled to the signal receiver 720. That is, wind speed sensing element 610 and wind direction sensing element 620 are each communicatively coupled to signal receiver 720. The signal receiver 720 is communicatively coupled to the controller 710, and the signal receiver 720 is configured to receive the wind force signal and transmit the wind force signal to the controller 710. The wind signals include a wind speed signal and a wind direction signal, that is, the signal receiver 720 is configured to receive the wind speed signal and the wind direction signal and transmit the wind speed signal and the wind direction signal to the controller 710. Controller 710 is communicatively coupled to signal transmitter 730, controller 710 is configured to transmit the wind force signal to signal transmitter 730, signal transmitter 730 is communicatively coupled to the receiving station, and signal transmitter 730 is configured to transmit the wind force signal to the receiving station. In this case, the wind monitoring assembly may detect the relevant data of the wind power and then transmit the relevant data to the signal receiver 720, and the signal receiver 720 collates the relevant data and transmits the collated data to the receiving station through the controller 710, so that the worker can remotely acquire the wind power data. It should be noted that the receiving station may be a computer or a mobile phone.

The wind monitoring apparatus may further include a control box 740, the control box 740 may be provided in the housing 100, and the controller 710, the signal receiver 720 and the signal transmitter 730 may be provided in the control box 740. Alternatively, the control box 740 may be disposed on an inner wall of the housing 100, or may be disposed on a side wall of the fixing rod 800.

While the present embodiments have been described with reference to the accompanying drawings, it is to be understood that the invention is not limited to the precise embodiments described above, which are meant to be illustrative and not restrictive, and that various changes may be made therein by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. A wind power monitoring device, comprising a housing (100), a cover (200), a wind power monitoring assembly and a first lifting mechanism (300), wherein: the cover body (200) is arranged on the shell body (100) in an openable and closable manner, the first lifting mechanism (300) is arranged in the shell body (100), the wind power monitoring assembly is arranged on the first lifting mechanism (300), and under the condition that the cover body (200) is in an opening state, the first lifting mechanism (300) can drive the wind power monitoring assembly to extend out of the shell body (100) or retract into the shell body (100).

2. The wind power monitoring device according to claim 1, further comprising an opening and closing assembly (400), wherein the opening and closing assembly (400) comprises a first connecting rod (410) and a second connecting rod (420), the first connecting rod (410) is hinged to the second connecting rod (420), the other end of the first connecting rod (410) is hinged to the housing (100), the other end of the second connecting rod (420) is hinged to the cover body (200), and the rotation of the first connecting rod (410) can sequentially drive the second connecting rod (420) and the cover body (200) to rotate, so that the cover body (200) can be switched between the open state and the closed state.

3. The wind power monitoring device according to claim 2, wherein the opening and closing assembly (400) further comprises a third connecting rod (430) and a fourth connecting rod (440), the third connecting rod (430) is hinged to the fourth connecting rod (440), the other end of the third connecting rod (430) is hinged to the housing (100), the other end of the fourth connecting rod (440) is hinged to the cover (200), the third connecting rod (430) is hinged to the second connecting rod (420), and when the second connecting rod (420) rotates, the second connecting rod (420) rotates to sequentially drive the third connecting rod (430), the fourth connecting rod (440) and the cover (200) to rotate.

4. A wind power monitoring device according to claim 3, characterized in that the inner wall of the housing (100) is provided with a first fixing member (450), the first connecting rod (410) and the third connecting rod (430) are hinged to the first fixing member (450), the inner wall of the cover (200) is provided with a second fixing member (460), and the second connecting rod (420) and the fourth connecting rod (440) are hinged to the second fixing member (460).

5. A wind power monitoring device according to claim 2, characterized in that the opening and closing assembly (400) further comprises a first power means (480), the first connecting rod (410) being connected to the first power means (480), the first power means (480) being adapted to drive the first connecting rod (410) in rotation.

6. The wind power monitoring device according to claim 1, wherein the first lifting mechanism (300) comprises a support (310), a screw (320) and a second power device (330), the wind power monitoring assembly is disposed on the support (310), the support (310) is in threaded connection with the screw (320), the screw (320) is in connection with the second power device (330), the second power device (330) is used for driving the screw (320) to rotate, and the rotation of the screw (320) can drive the support (310) and the wind power monitoring assembly to move.

7. A wind power monitoring device according to claim 6, characterized in that the first lifting mechanism (300) further comprises a guide (340), the guide (340) being provided in the housing (100), the support (310) being provided with a guiding structure, the guide (340) being in guiding engagement with the guiding structure in the direction of movement of the support (310).

8. The wind power monitoring device according to claim 6, further comprising a second lifting mechanism (500), wherein the second lifting mechanism (500) is disposed on the supporting member (310) so that the supporting member (310) drives the second lifting mechanism (500) to move, and the wind power monitoring assembly is disposed on the second lifting mechanism (500), and the second lifting mechanism (500) can drive the wind power monitoring assembly to move.

9. Wind power monitoring device according to claim 1, characterized in that the wind power monitoring assembly comprises a wind speed detection element (610), a wind direction detection element (620) and a wind direction auxiliary plate (621), one end of the wind direction auxiliary plate (621) being movably suspended to the wind direction detection element (620).

10. The wind monitoring device of claim 1, further comprising a controller (710), a signal receiver (720), and a signal transmitter (730), the wind monitoring assembly being communicatively coupled to the signal receiver (720), the signal receiver (720) being communicatively coupled to the controller (710), the controller (710) being communicatively coupled to the signal transmitter (730), the signal transmitter (730) being communicatively coupled to a receiving station;

the signal receiver (720) is used for receiving the wind power signal detected by the wind power monitoring assembly and transmitting the wind power signal to the controller (710), the controller (710) is used for transmitting the wind power signal to the signal transmitter (730), and the signal transmitter (730) is used for transmitting the wind power signal to the receiving station.