Power plant area temperature and humidity monitoring device

By designing a temperature and humidity monitoring device for power plant areas that includes the main body of the temperature and humidity monitoring equipment and moving components, and by utilizing the cooperation of lifting slide rails and winding rollers, the problem of incomplete detection in large power plant areas has been solved, enabling multi-point temperature and humidity detection and improving the comprehensiveness of the detection.

CN224416152UActive Publication Date: 2026-06-26国家能源集团泰州发电有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
国家能源集团泰州发电有限公司
Filing Date
2025-07-21
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

The power plant area is large, and the temperature and humidity monitoring devices are not easy to move, resulting in incomplete monitoring.

Method used

A temperature and humidity monitoring device for power plant areas was designed, comprising the main body of the temperature and humidity monitoring device and a moving component. By utilizing a lifting slide rail, a winding roller, guide wheels, and a moving trolley, the device can achieve multi-point detection of temperature and humidity. Through the cooperation of the lifting slide rail and the winding roller, longitudinal and lateral movement is achieved, improving the comprehensiveness of the detection.

Benefits of technology

It enables multi-point temperature and humidity monitoring within the power plant area, improving the comprehensiveness and coverage of the monitoring.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application provides a power plant area temperature and humidity monitoring device, and belongs to the technical field of monitoring devices. The power plant area temperature and humidity monitoring device comprises a temperature and humidity monitoring device body and a moving assembly. The moving assembly comprises lifting slide rails, winding rollers, first guide wheels, second guide wheels, pull ropes and moving trolleys. The lifting slide rails and the pull ropes are symmetrically arranged. The first guide wheels are rotationally connected to the upper portions of the lifting slide rails. The pull ropes are wound on the outer portions of the winding rollers. The temperature and humidity monitoring device body is fixedly connected to the upper portions of the moving trolleys. The moving trolleys move on the upper portions of the pull ropes. The tension of the pull ropes is adjusted, the height of the pull ropes drives the lifting of the moving trolleys, the moving trolleys realize longitudinal movement, the moving trolleys can longitudinally and transversely stop at multiple points, and thus multi-point temperature and humidity monitoring is realized, and the comprehensiveness of detection is improved.
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Description

Technical Field

[0001] This application relates to the field of monitoring equipment, and more specifically, to a temperature and humidity monitoring device for power plant areas. Background Technology

[0002] A power plant is a power plant that converts some form of virgin energy into electrical energy to power fixed facilities or transportation, such as thermal, hydroelectric, steam, diesel, or nuclear power plants. Currently, many places have coal-fired power plants. During power generation, the temperature and humidity in the plant area are high, thus requiring temperature and humidity monitoring devices. These devices are usually placed in a fixed location, but power plant areas are large, making it difficult to move the devices and resulting in incomplete monitoring. Utility Model Content

[0003] To overcome the above shortcomings, this application provides a temperature and humidity monitoring device for power plant areas, which aims to improve the problem that temperature and humidity detection devices are usually set up in a fixed location, but the power plant area is large and the temperature and humidity detection devices are not easy to move, resulting in insufficient detection.

[0004] This application provides a temperature and humidity monitoring device for a power plant area, including a temperature and humidity monitoring device body and a moving component. The moving component includes a lifting slide rail, a winding roller, a first guide wheel, a second guide wheel, a pull rope, and a moving trolley. The lifting slide rail and the pull rope are symmetrically arranged. The first guide wheel is rotatably connected to the upper part of one of the lifting slide rails, and the second guide wheel is rotatably connected to the upper part of the lifting end of one of the lifting slide rails. One end of the pull rope is wound around the outside of the winding roller, and the other end of the pull rope passes through the first guide wheel and the second guide wheel in sequence and is fixedly connected to the lifting end of another lifting slide rail. The temperature and humidity monitoring device body is fixedly connected to the upper part of the moving trolley, and the moving trolley moves on the upper part of the pull rope.

[0005] In one specific implementation, the lifting slide rail includes a frame, a first motor, a lead screw, and a lifting block. The first motor is fixedly connected to the upper part of the frame, the lead screw is rotatably connected to the frame, the lead screw is threadedly connected to the lifting block, the output end of the first motor is fixedly connected to one end of the lead screw, and the lifting block is slidably connected to the frame.

[0006] In one specific implementation, the take-up roller includes a second motor and a roller. The second motor is fixedly connected to one side of the upright, the roller is rotatably connected to the upright, the output end of the second motor is fixedly connected to the roller, and one end of the pull rope is wound around the outside of the roller.

[0007] In one specific implementation, the mobile trolley includes a frame, a walking wheel, and a drive wheel. The walking wheel and the drive wheel are both located at the bottom of the frame, and the pull rope passes through the drive wheel and the walking wheel in sequence.

[0008] In one specific implementation, the traveling wheel includes an upper traveling wheel, a first tensioning member, and a lower traveling wheel. The upper traveling wheel is rotatably connected to the frame, and the lower traveling wheel is rotatably connected to the first tensioning member. The first tensioning member is disposed at the bottom of the frame, and the upper traveling wheel and the lower traveling wheel are clamped to the outside of the pull rope.

[0009] In one specific implementation, the drive wheel includes an anti-slip wheel body, a second tensioning member, a tensioning wheel body, and a dual-axis motor. The anti-slip wheel body is rotatably connected to the frame, and the tensioning wheel body is rotatably connected to the second tensioning member, which is disposed at the bottom of the frame. The anti-slip wheel body and the tensioning wheel body are clamped outside the pull rope. The dual-axis motor is fixedly connected to the frame, and the output end of the dual-axis motor is fixedly connected to the anti-slip wheel body.

[0010] In one specific implementation, both the first tensioning member and the second tensioning member include a connecting block, a threaded rod, a spring, and a nut. The lower walking wheel is rotatably connected to one of the connecting blocks, and the tensioning wheel is rotatably connected to the other connecting block. The upper part of the connecting block is slidably connected to the frame. The threaded rod is fixedly connected to the bottom of the frame. The bottom of the threaded rod passes through the interior of the connecting block and is threadedly connected to the nut. The upper part of the spring abuts against the bottom of the connecting block, and the bottom of the spring abuts against the upper part of the nut.

[0011] In one specific implementation, a battery pack is provided on one side of the vehicle frame, a power distribution box is provided on the upper part of the vehicle frame, the battery pack is provided with a charging connector, a lifting block is provided with a charging plug, the charging plug is inserted into the charging connector, the power distribution box is electrically connected to the battery pack, and the power distribution box is electrically connected to the temperature and humidity monitoring device body and the dual-axis motor respectively.

[0012] Beneficial Effects: This application provides a temperature and humidity monitoring device for power plant areas. In use, two symmetrically arranged lifting rails are pre-installed, and then pull ropes are erected. The moving trolley is mounted on the upper part of the pull ropes, with the temperature and humidity monitoring device itself installed on top of the moving trolley. The moving trolley moves along the symmetrically arranged pull ropes, allowing for multi-point lateral temperature and humidity monitoring of the plant area. Simultaneously, the lifting ends of the two lifting rails can adjust the height of the pull ropes. When adjusting the height, the pull ropes need to be tensioned. A winding roller can be used to wind up the pull ropes to achieve tension. The height adjustment of the pull ropes drives the lifting and lowering of the moving trolley, enabling longitudinal movement. Therefore, the moving trolley can stop at multiple points both longitudinally and laterally, thus achieving multi-point temperature and humidity monitoring and improving the comprehensiveness of the monitoring. Attached Figure Description

[0013] To more clearly illustrate the technical solutions of the embodiments of this application, the drawings used in the embodiments will be briefly introduced below. It should be understood that the following drawings only show some embodiments of this application and should not be regarded as a limitation of the scope. For those skilled in the art, other related drawings can be obtained from these drawings without creative effort.

[0014] Figure 1 This is a schematic diagram of the structure of the power plant area temperature and humidity monitoring equipment provided in the embodiments of this application;

[0015] Figure 2 A partial structural schematic diagram of the lifting slide rail provided in the embodiments of this application;

[0016] Figure 3 A partial structural schematic diagram of the take-up roller provided in the embodiments of this application;

[0017] Figure 4 A partial structural schematic diagram of the mobile vehicle provided in the embodiments of this application from a first-view perspective;

[0018] Figure 5 A partial structural schematic diagram of the mobile vehicle provided in the embodiments of this application from a second perspective;

[0019] Figure 6 Provided for the implementation of this application Figure 5 A magnified schematic diagram of part of the structure in region A.

[0020] In the diagram: 100 - Temperature and humidity monitoring equipment body; 200 - Moving component; 210 - Lifting slide rail; 211 - Frame; 212 - First motor; 213 - Lead screw; 214 - Lifting block; 215 - Charging plug; 220 - Rewinding roller; 221 - Second motor; 222 - Roller; 230 - First guide wheel; 240 - Second guide wheel; 250 - Pull rope; 260 - Moving trolley; 261 - Frame; 262 - 2621-Traveling wheel; 2622-First tensioning element; 26221-Connecting block; 26222-Threaded rod; 26223-Spring; 26224-Nut; 2623-Traveling wheel; 263-Drive wheel; 2631-Anti-slip wheel body; 2632-Second tensioning element; 2633-Tensioning wheel body; 2634-Dual-axis motor; 265-Battery pack; 266-Power distribution box; 267-Charging connector. Detailed Implementation

[0021] The technical solutions in the embodiments of this application will now be described with reference to the accompanying drawings.

[0022] Please see Figure 1 This application provides a temperature and humidity monitoring device for a power plant area, including a temperature and humidity monitoring device body 100 and a moving component 200.

[0023] Please see Figures 1-6The moving component 200 includes a lifting slide rail 210, a take-up roller 220, a first guide wheel 230, a second guide wheel 240, a pull rope 250, and a moving trolley 260. The lifting slide rail 210 and the pull rope 250 are symmetrically arranged. The first guide wheel 230 is rotatably connected to the upper part of one lifting slide rail 210, and the second guide wheel 240 is rotatably connected to the upper part of the lifting end of one lifting slide rail 210. One end of the pull rope 250 is wound around the outside of the take-up roller 220, and the other end of the pull rope 250 passes through the first guide wheel 230 and the second guide wheel 240 in sequence and is fixedly connected to the lifting end of another lifting slide rail 210. The temperature and humidity monitoring device body 100 is fixedly connected to the upper part of the moving trolley 260, and the moving trolley 260 moves on the pull rope 250. The lifting slide rail 210 includes a frame 211, a first motor 212, a lead screw 213, and a lifting block. 214. The first motor 212 is fixedly connected to the upper part of the upright 211. The lead screw 213 is rotatably connected to the upright 211. The lead screw 213 is threadedly connected to the lifting block 214. The output end of the first motor 212 is fixedly connected to one end of the lead screw 213. The lifting block 214 is slidably connected to the upright 211. The winding roller 220 includes a second motor 221 and a roller 222. The second motor 221 is fixedly connected to one side of the upright 211. The roller 222 is rotatably connected to the upright 211. The output end of the second motor 221 is fixedly connected to the roller 222. One end of the pull rope 250 is wound around the outside of the roller 222. The moving trolley 260 includes a frame 261, a traveling wheel 262, and a drive wheel 263. The traveling wheel 262 and the drive wheel 263 are both located at the bottom of the frame 261. The pull rope 250 passes through the drive wheel 263 and the traveling wheel 262 in sequence.

[0024] The traveling wheel 262 includes an upper traveling wheel 2621, a first tensioning member 2622, and a lower traveling wheel 2623. The upper traveling wheel 2621 is rotatably connected to the frame 261, and the lower traveling wheel 2623 is rotatably connected to the first tensioning member 2622. The first tensioning member 2622 is located at the bottom of the frame 261. The upper traveling wheel 2621 and the lower traveling wheel 2623 are clamped to the outside of the pull rope 250. The drive wheel 263 includes an anti-slip wheel body 2631, a second tensioning member 2632, a tensioning wheel body 2633, and a dual-axis motor 26. 34. The anti-slip wheel body 2631 is rotatably connected to the frame 261, and the tension wheel body 2633 is rotatably connected to the second tensioning member 2632. The second tensioning member 2632 is located at the bottom of the frame 261. The anti-slip wheel body 2631 and the tension wheel body 2633 are clamped outside the pull rope 250. The dual-axis motor 2634 is fixedly connected to the frame 261, and the output end of the dual-axis motor 2634 is fixedly connected to the anti-slip wheel body 2631. Both the first tensioning member 2622 and the second tensioning member 2632 include a connecting block 26221 and a screw. The components include a threaded rod 26222, a spring 26223, and a nut 26224. The lower travel wheel 2623 is rotatably connected to a connecting block 26221, and the tension wheel body 2633 is rotatably connected to another connecting block 26221. The upper part of the connecting block 26221 is slidably connected to the frame 261. The threaded rod 26222 is fixedly connected to the bottom of the frame 261, and the bottom of the threaded rod 26222 passes through the interior of the connecting block 26221 and is threadedly connected to the nut 26224. The upper part of the spring 26223 abuts against the connecting block 26221. At the bottom, the bottom of the spring 26223 abuts against the upper part of the nut 26224. A battery pack 265 is provided on one side of the frame 261, and a power distribution box 266 is provided on the upper part of the frame 261. The battery pack 265 is provided with a charging connector 267. A lifting block 214 is provided with a charging plug 215, which is inserted into the charging connector 267. The power distribution box 266 is electrically connected to the battery pack 265. The power distribution box 266 is also electrically connected to the temperature and humidity monitoring equipment body 100 and the dual-axis motor 2634.

[0025] The working principle of this power plant area temperature and humidity monitoring equipment is as follows: First, two symmetrical lifting slide rails 210 are installed, then a pull rope 250 is erected. The traveling wheel 262 and drive wheel 263 are placed on the pull rope 250. Then, the temperature and humidity monitoring equipment body 100 is mounted on a mobile trolley 260. The drive wheel 263 drives the trolley frame 261 to move laterally along the pull rope 250 with the cooperation of the traveling wheel 262, achieving multi-point lateral temperature and humidity detection in the plant area. The output of the first motor 212 drives... When the lead screw 213 rotates, it drives the lifting block 214 to rise and fall. The lifting block 214 can also drive the rise and fall of one end of the pull rope 250. The lifting block 214 can change the height of the pull rope 250. Through the output end of the second motor 221, it drives the roller 222 to rotate, and the pull rope 250 is wound up to keep it taut. The adjustment of the height of the pull rope 250 drives the moving trolley 260 to rise and fall longitudinally. In this way, the moving trolley 260 can stop at multiple positions in the horizontal and vertical directions, realize multi-point temperature and humidity monitoring, and improve the comprehensiveness of detection.

[0026] The above description is merely an embodiment of this application and is not intended to limit the scope of protection of 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 scope of protection of this application. It should be noted that similar reference numerals and letters in the following figures indicate similar items; therefore, once an item is defined in one figure, it does not need to be further defined and explained in subsequent figures.

Claims

1. A temperature and humidity monitoring device for power plant areas, characterized in that, include Temperature and humidity monitoring equipment body (100); A moving component (200) includes a lifting slide rail (210), a take-up roller (220), a first guide wheel (230), a second guide wheel (240), a pull rope (250), and a moving trolley (260). The lifting slide rail (210) and the pull rope (250) are symmetrically arranged. The first guide wheel (230) is rotatably connected to the upper part of one of the lifting slide rails (210), and the second guide wheel (240) is rotatably connected to the upper part of the lifting slide rail (260). At the upper part of the lifting end of the slide rail (210), one end of the pull rope (250) is wound around the outside of the take-up roller (220), and the other end of the pull rope (250) passes through the first guide wheel (230) and the second guide wheel (240) in sequence and is fixedly connected to the lifting end of another lifting slide rail (210). The body (100) of the temperature and humidity monitoring device is fixedly connected to the upper part of the mobile trolley (260), and the mobile trolley (260) moves on the upper part of the pull rope (250).

2. The power plant area temperature and humidity monitoring device according to claim 1, characterized in that, The lifting slide rail (210) includes a frame (211), a first motor (212), a lead screw (213), and a lifting block (214). The first motor (212) is fixedly connected to the upper part of the frame (211), the lead screw (213) is rotatably connected to the frame (211), the lead screw (213) is threadedly connected to the lifting block (214), the output end of the first motor (212) is fixedly connected to one end of the lead screw (213), and the lifting block (214) is slidably connected to the frame (211).

3. The power plant area temperature and humidity monitoring device according to claim 2, characterized in that, The take-up roller (220) includes a second motor (221) and a roller (222). The second motor (221) is fixedly connected to one side of the upright (211), and the roller (222) is rotatably connected to the upright (211). The output end of the second motor (221) is fixedly connected to the roller (222), and one end of the pull rope (250) is wound around the outside of the roller (222).

4. The power plant area temperature and humidity monitoring device according to claim 3, characterized in that, The mobile trolley (260) includes a frame (261), a walking wheel (262) and a drive wheel (263). The walking wheel (262) and the drive wheel (263) are both located at the bottom of the frame (261). The pull rope (250) passes through the drive wheel (263) and the walking wheel (262) in sequence.

5. A power plant area temperature and humidity monitoring device according to claim 4, characterized in that, The walking wheel (262) includes an upper walking wheel (2621), a first tensioning member (2622), and a lower walking wheel (2623). The upper walking wheel (2621) is rotatably connected to the frame (261), and the lower walking wheel (2623) is rotatably connected to the first tensioning member (2622). The first tensioning member (2622) is located at the bottom of the frame (261), and the upper walking wheel (2621) and the lower walking wheel (2623) are clamped to the outside of the pull rope (250).

6. The power plant area temperature and humidity monitoring device according to claim 5, characterized in that, The drive wheel (263) includes an anti-slip wheel body (2631), a second tensioning member (2632), a tensioning wheel body (2633), and a dual-axis motor (2634). The anti-slip wheel body (2631) is rotatably connected to the frame (261), and the tensioning wheel body (2633) is rotatably connected to the second tensioning member (2632). The second tensioning member (2632) is located at the bottom of the frame (261). The anti-slip wheel body (2631) and the tensioning wheel body (2633) are clamped outside the pull rope (250). The dual-axis motor (2634) is fixedly connected to the frame (261), and the output end of the dual-axis motor (2634) is fixedly connected to the anti-slip wheel body (2631).

7. The power plant area temperature and humidity monitoring device according to claim 6, characterized in that, Both the first tensioning member (2622) and the second tensioning member (2632) include a connecting block (26221), a threaded rod (26222), a spring (26223), and a nut (26224). The lower wheel (2623) is rotatably connected to one of the connecting blocks (26221), and the tensioning wheel body (2633) is rotatably connected to the other connecting block (26221). The upper part of the connecting block (26221) is slidably connected to the frame (261). The threaded rod (26222) is fixedly connected to the bottom of the frame (261). The bottom of the threaded rod (26222) passes through the interior of the connecting block (26221) and is threadedly connected to the nut (26224). The upper part of the spring (26223) abuts against the bottom of the connecting block (26221), and the bottom of the spring (26223) abuts against the upper part of the nut (26224).

8. The power plant area temperature and humidity monitoring device according to claim 7, characterized in that, A battery pack (265) is provided on one side of the frame (261), and a power distribution box (266) is provided on the upper part of the frame (261). The battery pack (265) is provided with a charging connector (267), and a lifting block (214) is provided with a charging plug (215). The charging plug (215) is inserted into the charging connector (267). The power distribution box (266) is electrically connected to the battery pack (265), and the power distribution box (266) is electrically connected to the temperature and humidity monitoring device body (100) and the dual-axis motor (2634) respectively.