A new energy station panoramic monitoring device

Abstract

This application discloses a panoramic monitoring device for new energy power stations, belonging to the technical field of monitoring equipment. It mainly includes: a support rod; an angle adjustment component mounted on the support rod; the angle adjustment component includes an assembly plate mounted on the support rod, a first drive motor mounted on the assembly plate, and an assembly box mounted on the output end of the first drive motor; and a position adjustment component mounted on the assembly box, the position adjustment component including a one-way lead screw driven and rotatably connected within the assembly box. In this panoramic monitoring device for new energy power stations, the angle adjustment component and the position adjustment component cooperate to flexibly adjust the position of the panoramic camera according to the actual monitoring needs of the new energy power station, ensuring stable operation of the device in complex outdoor environments and reducing the existence of blind spots, thus meeting the monitoring requirements of new energy power stations.

Description

Technical Field

[0001] This application relates to the field of monitoring equipment technology, specifically a panoramic monitoring device for new energy power stations. Background Technology

[0002] New energy power plants, such as photovoltaic power plants and wind power plants, typically occupy a large area and have widely distributed equipment. Installing surveillance cameras in these plants can achieve monitoring coverage of the plants, and both the operating status of the equipment and the security situation around the plants can be clearly presented through the cameras.

[0003] For example, patent CN219893364U discloses a panoramic monitoring device for new energy power stations, including a central control unit, a monitoring module, a reducer, a threaded rod, and a threaded column. The beneficial effect of this invention is that when the external monitoring camera is working, the air pump causes the airflow nozzle to generate high-pressure airflow, forming a wind wall in front of the lens to block rainwater and ensure clear imaging; the motor can also drive the airflow nozzle to rotate, aligning the nozzle with the lens for regular cleaning.

[0004] However, the panoramic monitoring device mentioned above relies solely on a single threaded rod and threaded column to adjust the height of the camera. This not only limits the adjustment dimensions but also makes it difficult to adjust the lateral position of the camera. It is also difficult to flexibly cover areas with elevation differences or complex layouts in the station. Due to the scattered distribution of station equipment and diverse terrain, this limited adjustment method makes it difficult for the camera to fully cover multiple corners, easily creating blind spots in the monitoring. This makes it difficult to meet the needs of new energy power stations for real-time monitoring of the entire area, affecting the overall monitoring effect. Therefore, it is necessary to provide a panoramic monitoring device for new energy power stations to solve the above problems. Summary of the Invention

[0005] Based on the aforementioned problems in the existing technology, the problem to be solved by this application is to provide a panoramic monitoring device for new energy power stations, which solves the problems of limited adjustment dimensions, difficulty in adjusting the lateral position, difficulty in covering areas with elevation differences or complex layouts, resulting in monitoring blind spots and difficulty in meeting the real-time monitoring needs of the entire new energy power station.

[0006] The technical solution adopted by this application to solve its technical problem is: a panoramic monitoring device for new energy power stations, comprising:

[0007] Support rod;

[0008] An angle adjustment assembly is mounted on the support rod. The angle adjustment assembly includes an assembly plate mounted on the support rod, a first drive motor is mounted on the assembly plate, and an assembly box is mounted on the output end of the first drive motor.

[0009] A position adjustment assembly is installed on the assembly box. The position adjustment assembly includes a one-way lead screw that is driven and rotatably connected to the assembly box. A one-way slider is sleeved on the body of the one-way lead screw. A middle block is installed on one side of the one-way slider. A guide groove suitable for the sliding of the middle block is provided on one side of the assembly box. A middle frame is installed on one side of the middle block. A panoramic camera is installed on the middle frame.

[0010] Furthermore, a support plate is installed on one side of the support rod, and multiple intermediate plates are installed on the support plate. A limit ring is installed on the intermediate plate, and a limit groove is provided on one side of the limit ring.

[0011] The assembly box is equipped with two sets of adapter frames, and each adapter frame is equipped with a slip ring that can slide within the limiting groove.

[0012] Furthermore, the assembly box has a hollow box structure.

[0013] Furthermore, two sets of support plates are installed on the support plate, and the intermediate plate is connected to the support plates by bolts.

[0014] Furthermore, a second drive motor is installed on the assembly box, and the output end of the second drive motor extends into the assembly box and is connected to one end of the one-way lead screw.

[0015] Furthermore, the other end of the one-way lead screw is rotatably connected to the assembly box.

[0016] Furthermore, the two sets of support plates are symmetrically distributed on the support disk.

[0017] The beneficial effects of this application are: In the panoramic monitoring device for new energy power stations provided by this application, the angle adjustment component and the position adjustment component work together to flexibly adjust the position of the panoramic camera according to the actual monitoring needs of the new energy power station, ensuring that the device operates stably in complex outdoor environments and reducing the existence of monitoring blind spots, thereby meeting the monitoring needs of new energy power stations.

[0018] In addition to the purposes, features, and advantages described above, this application has other purposes, features, and advantages. A further detailed description of this application will be provided below with reference to the figures. Attached Figure Description

[0019] The accompanying drawings, which form part of this application, are used to provide a further understanding of this application. The illustrative embodiments and descriptions of this application are used to explain this application and do not constitute an undue limitation of this application. In the drawings:

[0020] Figure 1This is a first three-dimensional structural schematic diagram of a panoramic monitoring device for a new energy power station according to an embodiment of this application;

[0021] Figure 2 According to the embodiments of this application Figure 1 Enlarged view of point A in the middle;

[0022] Figure 3 This is a partial three-dimensional structural schematic diagram of a panoramic monitoring device for a new energy power station according to an embodiment of this application;

[0023] Figure 4 This is a three-dimensional structural schematic diagram of the angle adjustment component according to an embodiment of this application;

[0024] Figure 5 According to the embodiments of this application Figure 4 Enlarged view of point B in the middle;

[0025] Figure 6 This is a three-dimensional structural diagram of the angle adjustment component and the position adjustment component according to embodiments of this application.

[0026] The following are the labeling elements in the figure:

[0027] 1. Monitoring component; 11. Base; 12. Support rod; 2. Angle adjustment component; 21. Support plate; 22. Support disc; 23. Intermediate plate; 24. Limiting ring; 25. Limiting groove; 26. Assembly disc; 261. First drive motor; 27. Assembly box; 271. Adapter frame; 272. Slip ring; 3. Position adjustment component; 31. Second drive motor; 32. One-way lead screw; 33. One-way slider; 34. Intermediate block; 35. Guide groove; 36. Intermediate frame; 37. Panoramic camera. Detailed Implementation

[0028] It should be noted that, unless otherwise specified, the embodiments and features described in this application can be combined with each other. This application will now be described in detail with reference to the accompanying drawings and embodiments.

[0029] To enable those skilled in the art to better understand the present application, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present application, and not all embodiments. Based on the embodiments in the present application, all other embodiments obtained by those of ordinary skill in the art without creative effort should fall within the scope of protection of the present application.

[0030] like Figure 1As shown, this application provides a panoramic monitoring device for new energy power stations, including a monitoring component 1. The monitoring component 1 is the basic support part of the entire device and has a stable structure. The monitoring component 1 includes a base 11, which serves as the bottom support structure of the monitoring component 1. It is made of cast iron and is firmly fixed to the ground by means of anchor bolts (not shown in the figure) to ensure that the entire device can stand stably in complex outdoor environments and is not prone to tilting or displacement due to wind, vibration, or other factors. A support rod 12 is fixedly installed at the upper end of the base 11. The support rod 12 is a long rod made of stainless steel and provides a basic carrier for the installation of subsequent angle adjustment parts and position adjustment parts.

[0031] like Figures 1-4 and Figure 6 As shown, an angle adjustment assembly 2 is installed on the support rod 12. The angle adjustment assembly 2 is used to adjust the monitoring angle. The angle adjustment assembly 2 includes a support plate 22 fixedly installed on the support rod 12. The support plate 22 is a circular metal plate that is tightly fixed to the upper part of the support rod 12 by welding, and plays a supporting role. On one side of the support plate 22, two sets of symmetrically arranged support plates 21 are fixedly installed. These two sets of support plates 21 are symmetrically distributed on the support plate 22, which can evenly distribute and bear the force from above, ensuring the stability of the structure. At the same time, the material of the support plate 21 is the same as that of the support rod 12 and the support plate 22, which is also a high-strength metal material.

[0032] Multiple intermediate plates 23 are also fixedly installed on the support plate 22. These intermediate plates 23 are connected to the support plate 21 by bolts. The bolt connection method facilitates installation and disassembly, and also ensures the firmness of the connection, so that the intermediate plates 23 and the support plate 21 form a stable overall structure. At the end of the intermediate plate 23 away from the support plate 22, a limiting ring 24 is fixedly installed. The limiting ring 24 is a ring-shaped metal component with a limiting groove 25 on one side.

[0033] An assembly plate 26 is bolted onto the support rod 12, and a first drive motor 261 is bolted onto the assembly plate 26. The first drive motor 261 is the power source for the angle adjustment component 2. It is electrically connected to an external power source and started by a controller. Its output end has sufficient torque and speed. The output end of the first drive motor 261 passes through the support rod 12 and the support plate 22, and then an assembly box 27 is installed. The assembly box 27 is a hollow box structure used to accommodate some parts of the position adjustment part.

[0034] At the upper and lower ends of the middle part of the assembly box 27, a transition frame 271 is fixedly installed. At one end of the transition frame 271, a slip ring 272 that can slide within the limiting groove 25 is fixedly installed. The slip ring 272 and the limiting groove 25 have a high fitting precision, which allows it to slide smoothly within the limiting groove 25, while ensuring that it will not easily disengage during the sliding process. Thus, when the first drive motor 261 drives the assembly box 27 to rotate, it provides stable support and guidance for the assembly box 27, ensuring the smooth adjustment of the angle.

[0035] like Figure 3 , Figure 5 and Figure 6 As shown, a position adjustment component 3 is installed on the assembly box 27. The position adjustment component 3 is used to adjust the lateral position of the monitoring part to cover areas with elevation differences or complex layouts, which can meet the needs of real-time monitoring of the entire area of ​​new energy power stations. The position adjustment component 3 includes a second drive motor 31 that is bolted to one end of the assembly box 27. The second drive motor 31 is also a power component. After being powered on, it provides power to the position adjustment component 3 through the corresponding controller.

[0036] The output end of the second drive motor 31 extends into the assembly box 27 and is coaxially mounted with a one-way lead screw 32. A one-way slider 33 is threadedly connected to the body of the one-way lead screw 32. An intermediate block 34 is fixedly mounted on one side of the one-way slider 33. A guide groove 35 suitable for the sliding of the intermediate block 34 is provided on one side of the assembly box 27. The guide groove 35 provides a track for the sliding of the intermediate block 34, ensuring that the intermediate block 34 will not deviate during the sliding process and ensuring the accuracy of position adjustment. An intermediate frame 36 is bolted to one side of the intermediate block 34, and a panoramic camera 37 is bolted to the intermediate frame 36.

[0037] Among them, the intermediate frame 36 is a bridge connecting the intermediate block 34 and the panoramic camera 37. It can bear the weight of the panoramic camera 37 and ensure the stable installation of the panoramic camera 37. Meanwhile, the panoramic camera 37 is a component for realizing panoramic monitoring, which can capture images and videos within a wide field of view. By adjusting the position adjustment component 3, the panoramic camera 37 can be moved to a suitable position, thereby realizing comprehensive monitoring of different areas of the new energy power station.

[0038] Specifically, starting the second drive motor 31 can rotate the one-way lead screw 32. At this time, the one-way slider 33 will slide along the axial direction of the one-way lead screw 32. This sliding is because the rotational motion of the one-way lead screw 32 is converted into the linear motion of the one-way slider 33 through the thread structure. The sliding of the one-way slider 33 will drive the connected intermediate block 34 to slide synchronously in the guide groove 35. Then, through the intermediate frame 36, the panoramic camera 37 will move in the length direction of the assembly box 27, realizing the precise adjustment of the lateral position of the panoramic camera 37. This can adapt to different monitoring needs, expand the monitoring range, and ensure that all areas of the new energy power station can be monitored comprehensively and meticulously, avoiding monitoring blind spots.

[0039] Working principle: The panoramic monitoring device for new energy power stations is based on the monitoring component 1. The cast iron base 11 is fixed to the ground with anchor bolts to ensure the stability of the device in the outdoor environment. The stainless steel support rod 12 provides the mounting carrier for the angle adjustment component 2 and the position adjustment component 3.

[0040] During the angle adjustment process, the first drive motor 261 is started by the external controller. The first drive motor 261 is electrically connected to the external power supply. Its output end generates rotational power and drives the assembly box 27 to rotate. The adapter frame 271 at the upper and lower ends of the middle of the assembly box 27 moves together, so that the slip ring 272 slides smoothly in the limiting groove 25 of the limiting ring 24. This structure not only provides precise guidance for the rotation of the assembly box 27, but also effectively distributes the load and ensures the stability of the angle adjustment. By controlling the rotation direction and angle of the first drive motor 261, the panoramic camera 37 can be driven to achieve 360-degree horizontal rotation, thereby adjusting the monitoring angle.

[0041] When adjusting the position, the second drive motor 31 is started by the corresponding controller, and its output end drives the one-way lead screw 32 to rotate. Since the one-way slider 33 is threadedly connected to the one-way lead screw 32, the rotational motion is converted into the axial linear motion of the one-way slider 33, which in turn drives the middle block 34 to slide along the guide groove 35. The panoramic camera 37 is pushed by the middle frame 36 to achieve lateral position adjustment. By controlling the operating parameters of the second drive motor 31, the lateral displacement distance of the panoramic camera 37 can be adjusted.

[0042] The angle adjustment component 2 and the position adjustment component 3 work together to flexibly adjust the position of the panoramic camera 37 according to the actual monitoring needs of the new energy power station, ensuring stable operation of the device in complex outdoor environments and reducing the existence of monitoring blind spots, thus meeting the monitoring needs of the new energy power station.

[0043] The above description is merely a preferred embodiment of this application and is not intended to limit this application. Various modifications and variations can be made to this application by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this application should be included within the protection scope of this application.

Claims

1. A panoramic monitoring device for new energy power stations, characterized in that: include: Support rod (12); An angle adjustment assembly (2) is mounted on the support rod (12). The angle adjustment assembly (2) includes an assembly plate (26) mounted on the support rod (12). A first drive motor (261) is mounted on the assembly plate (26). An assembly box (27) is mounted on the output end of the first drive motor (261). A position adjustment component (3) is installed on the assembly box (27). The position adjustment component (3) includes a one-way lead screw (32) that is driven and rotatably connected to the assembly box (27). A one-way slider (33) is sleeved on the body of the one-way lead screw (32). A middle block (34) is installed on one side of the one-way slider (33). A guide groove (35) suitable for sliding the middle block (34) is provided on one side of the assembly box (27). A middle frame (36) is installed on one side of the middle block (34). A panoramic camera (37) is installed on the middle frame (36).

2. The panoramic monitoring device for new energy power stations according to claim 1, characterized in that: A support plate (22) is installed on one side of the support rod (12), and a plurality of intermediate plates (23) are installed on the support plate (22). A limit ring (24) is installed on the intermediate plate (23), and a limit groove (25) is provided on one side of the limit ring (24). Two sets of adapter frames (271) are installed on the assembly box (27), and a slip ring (272) that can slide within the limiting groove (25) is installed on the adapter frame (271).

3. The panoramic monitoring device for new energy power stations according to claim 2, characterized in that: The assembly box (27) has a hollow box structure.

4. A panoramic monitoring device for new energy power stations according to claim 2, characterized in that: Two sets of support plates (21) are installed on the support plate (22), and the intermediate plate (23) is connected to the support plate (21) by bolts.

5. A panoramic monitoring device for new energy power stations according to claim 1, characterized in that: A second drive motor (31) is installed on the assembly box (27), and the output end of the second drive motor (31) extends into the assembly box (27) and is connected to one end of the one-way lead screw (32).

6. A panoramic monitoring device for new energy power stations according to claim 5, characterized in that: The other end of the unidirectional lead screw (32) is rotatably connected to the assembly box (27).

7. A panoramic monitoring device for new energy power stations according to claim 4, characterized in that: The two sets of support plates (21) are symmetrically distributed on the support disk (22).

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