A device management monitoring apparatus
By introducing heat dissipation components and a convenient installation structure into the experimental equipment monitoring device, the problem of component overheating caused by high temperature in the monitoring device is solved, achieving efficient heat dissipation and convenient installation, and improving monitoring accuracy and component life.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 武汉奇域电子有限公司
- Filing Date
- 2025-05-30
- Publication Date
- 2026-07-14
AI Technical Summary
Existing experimental equipment monitoring devices are prone to overheating of internal electronic components due to high temperatures after prolonged use, which reduces the lifespan of the monitoring module and affects the accuracy of data monitoring.
It adopts a combination structure of heat sink, circulation pipe, inlet and outlet pipe, heat conduction plate, heat dissipation grid plate and heat dissipation copper fin assembly. It achieves efficient heat dissipation by electrically driving coolant circulation and combining it with ventilation. At the same time, it can be easily installed and fixed by utilizing the sliding and snap-fit structure of the mounting frame.
It effectively reduces the temperature of the monitoring device, extends the service life of internal components, improves the accuracy of data monitoring, and enhances the ease of device installation.
Smart Images

Figure CN224503766U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of experimental equipment monitoring technology, specifically to an equipment management and monitoring device. Background Technology
[0002] The normal operation of experimental equipment is crucial to the accuracy and reliability of experimental results. During the operation of experimental equipment, monitoring devices are needed to monitor and protect the equipment data in real time, and comprehensively acquire the equipment's operating parameters, such as temperature, pressure, and vibration.
[0003] Under prolonged monitoring, the monitoring device box of existing experimental equipment is prone to generating high temperatures inside, which leads to the high-temperature operation of internal electronic components, causing them to operate under heavy load, reducing the lifespan of the monitoring module, and affecting the accuracy of real-time monitoring of equipment data. Utility Model Content
[0004] The purpose of this invention is to provide an equipment management and monitoring device to solve the problems mentioned in the background art.
[0005] To solve the above-mentioned technical problems, the technical solution adopted by this utility model is as follows:
[0006] An equipment management and monitoring device includes an experimental equipment monitoring box. An assembly rack is movably installed inside the experimental equipment monitoring box. A monitoring equipment component is fixedly installed on the top of the assembly rack. A data processing module is fixedly installed inside the monitoring equipment component. A monitoring module is fixedly connected to the side of the data processing module. A monitoring display screen is fixedly installed on the top of the inner cavity of the experimental equipment monitoring box. A ventilation fan is fixedly installed on the right side of the experimental equipment monitoring box.
[0007] The assembly frame has a disassembly groove inside, and an installation plate is detachably connected inside the disassembly groove. The surface of the installation plate has ventilation grooves.
[0008] The assembly frame has sliding grooves on both sides, and a sliding frame is movably installed inside the sliding grooves. One end of the sliding frame is fixedly installed on the inner wall of the experimental equipment monitoring box.
[0009] A further improvement of this utility model is that: heat dissipation plates are fixedly installed at both ends of the mounting plate, a circulation pipe is fixedly installed inside the heat dissipation plate, and an inlet / outlet pipe is fixedly connected to one end of the circulation pipe.
[0010] By adopting the above technical solution, the heat sink, circulation pipe and inlet and outlet pipes work together to input coolant into the interior through the inlet and outlet pipes. With the help of electric power, the circulation pipe drives the coolant to circulate in the pipe, and while flowing, it carries away some heat, thereby achieving the function of heat dissipation.
[0011] A further improvement of this utility model is that: a heat-conducting plate is fixedly installed on the top of the heat sink, a heat-conducting grid plate is fixedly installed inside the heat-conducting plate, a connecting plate is fixedly installed on the top of the heat-conducting grid plate, and a heat-conducting copper fin assembly is fixedly installed on the top of the connecting plate.
[0012] By adopting the above technical solution, the heat-conducting plate, heat dissipation grid plate, connecting plate and heat dissipation copper fin assembly work together to utilize the permeability and heat absorption properties of the copper fin assembly to perform secondary heat dissipation on the circulation pipe, thereby improving the efficiency of circulation heat dissipation.
[0013] A further improvement of this utility model is that a support baffle is fixedly installed on the inner side of the sliding frame, and a protective pad is fixedly installed on the top of the support baffle.
[0014] By adopting the above technical solution, the protective support function is achieved through the cooperation of the support baffle and the protective pad.
[0015] A further improvement of this utility model is that a rubber pad is fixedly installed on the surface of the protective pad, and the top of the rubber pad is located at the bottom of the assembly frame.
[0016] By adopting the above technical solution, the function of noise reduction installation is achieved through the cooperation of protective pads, rubber pads and assembly frames.
[0017] A further improvement of this utility model is that: the top of both ends of the assembly frame is provided with a movable groove, a locking block is movably installed inside the movable groove, and a locking pin is movably installed on the inner wall of the movable groove.
[0018] By adopting the above technical solution, the sliding limit function is achieved through the cooperation of the moving groove, the locking block and the locking pin.
[0019] A further improvement of this utility model is that: the sliding frame has connecting grooves at both ends, and the interior of the connecting grooves is movably connected to one end of the locking block.
[0020] By adopting the above technical solution, the connecting groove and the sliding bracket cooperate to achieve the function of snap-fit fixation.
[0021] Due to the adoption of the above technical solution, the technological progress achieved by this utility model compared to the prior art is as follows:
[0022] 1. This utility model provides an equipment management and monitoring device, which uses a heat dissipation plate, a circulation pipe, an inlet and outlet pipe, a heat conduction plate, a slide groove, a heat dissipation grid plate, a connecting plate, and a heat dissipation copper fin assembly to work together. The circulation pipe is driven by electricity to move the internal coolant in a circulation manner. While moving, the coolant absorbs and carries away some heat, thereby achieving the function of water circulation cooling and heat dissipation. The heat dissipation copper fin assembly then performs rapid heat exchange, and the permeability of the heat dissipation grid plate and the connecting plate is used to achieve the function of ventilation and heat dissipation, thereby accelerating the heat dissipation effect of the heat dissipation mechanism.
[0023] 2. This utility model provides an equipment management and monitoring device. Through the cooperation of connecting groove, moving groove, locking block and locking pin, the assembly frame is slidably inserted into the inner side of the sliding frame to achieve the function of sliding installation. The moving locking block is locked inside the connecting groove, and then the moving locking pin is used for limiting and locking to achieve the function of fixed installation. This facilitates the convenient installation and disassembly of the assembly frame. Attached Figure Description
[0024] Figure 1 This is a schematic diagram of the structure of this utility model;
[0025] Figure 2 This is a schematic diagram of the assembly frame structure of this utility model;
[0026] Figure 3 This is a schematic diagram of the heat-conducting plate structure of this utility model;
[0027] Figure 4 This is a schematic diagram of the assembly frame structure of this utility model;
[0028] Figure 5 This is an enlarged view of section A of this utility model.
[0029] In the diagram: 1. Experimental equipment monitoring box; 2. Assembly rack; 3. Monitoring equipment components; 4. Monitoring display screen; 5. Ventilation fan; 21. Disassembly slot; 22. Mounting plate; 23. Ventilation slot; 24. Heat sink; 25. Circulation pipe; 26. Inlet and outlet pipes; 27. Heat conduction plate; 28. Slide groove; 271. Heat dissipation grille; 272. Connecting plate; 273. Heat dissipation copper fin assembly; 281. Sliding frame; 282. Support baffle; 283. Protective pad; 284. Connecting slot; 285. Moving slot; 286. Locking block; 287. Locking pin. Detailed Implementation
[0030] The present invention will be further described in detail below with reference to embodiments:
[0031] Example 1
[0032] like Figure 1-5As shown, this utility model provides an equipment management and monitoring device, including an experimental equipment monitoring box 1. An assembly frame 2 is movably installed inside the experimental equipment monitoring box 1. A monitoring equipment component 3 is fixedly installed on the top of the assembly frame 2. A data processing module is fixedly installed inside the monitoring equipment component 3. A monitoring module is fixedly connected to the side of the data processing module. A monitoring display screen 4 is fixedly installed on the top of the inner cavity of the experimental equipment monitoring box 1. A ventilation fan 5 is fixedly installed on the right side of the experimental equipment monitoring box 1. A disassembly groove 21 is opened inside the assembly frame 2. An installation plate 22 is detachably connected inside the disassembly groove 21. A ventilation groove 23 is opened on the surface of the installation plate 22. Heat dissipation plates 24 are fixedly installed at both ends of the installation plate 22. A circulation pipe 25 is fixedly installed inside the heat dissipation plate 24. An inlet / outlet pipe 26 is fixedly connected to one end of the circulation pipe 25. A heat-conducting plate 27 is fixedly installed on the top of the heat dissipation plate 24. A heat dissipation grille 271 is fixedly installed, and a connecting plate 272 is fixedly installed on the top of the heat dissipation grille 271. A heat dissipation copper fin assembly 273 is fixedly installed on the top of the connecting plate 272. The analog signal input from the sensor is converted into a digital signal by the data processing module, and the digital signal is filtered and amplified. At the same time, it judges whether the experimental equipment is in normal operation according to the preset threshold, and monitors the data of the experimental equipment in conjunction with the monitoring module and provides real-time warnings. The monitoring equipment component 3 monitors the high temperature generated in real time and transfers it to the assembly frame 2. With the help of electric drive, the coolant inside the circulation pipe 25 moves, and the movement of the coolant carries away some of the heat, thereby achieving the function of water circulation heat exchange. Then, the heat dissipation copper fin assembly 273 has the function of fast heat conduction, and with the permeability of the heat dissipation grille 271, ventilation and heat dissipation are carried out, which accelerates the heat dissipation efficiency of water circulation and is beneficial to the heat dissipation protection of the device.
[0033] Example 2
[0034] like Figure 1-5 As shown, based on Embodiment 1, this utility model provides a technical solution: Preferably, the assembly frame 2 has sliding grooves 28 on both sides, and a sliding frame 281 is movably installed inside the sliding grooves 28. One end of the sliding frame 281 is fixedly installed on the inner wall of the experimental equipment monitoring box 1. A support baffle 282 is fixedly installed on the inner side of the sliding frame 281. A protective pad 283 is fixedly installed on the top of the support baffle 282. A rubber pad is fixedly installed on the surface of the protective pad 283. The top of the rubber pad is located at the bottom of the assembly frame 2. The assembly frame 2 is slidably connected to the inner side of the sliding frame 281 through the sliding grooves 28. The support baffle 282 and the protective pad 283 are installed at the bottom of one end of the assembly frame 2. The softness of the protective pad 283 and the rubber pad increases the stability of the bottom support, which is conducive to the stable installation of the device and reduces the generation of noise.
[0035] Example 3
[0036] like Figure 1-5 As shown, based on Embodiment 1, this utility model provides a technical solution: Preferably, the top of both ends of the assembly frame 2 is provided with a movable groove 285, the inside of the movable groove 285 is movably installed with a locking block 286, and the inner wall of the movable groove 285 is movably installed with a locking pin 287. Both ends of the sliding frame 281 are provided with a connecting groove 284, the inside of the connecting groove 284 is movably connected to one end of the locking block 286, and the assembly frame 2 is slidably inserted into the inner side of the sliding frame 281, which facilitates the sliding installation of the installation mechanism, increases convenience, and the movable locking block 286 is locked inside the connecting groove 284, and then the movable locking pin 287 is locked at the rear end of the locking block 286 for limiting, which facilitates the fixed installation of the installation mechanism and is beneficial to the stability of the assembly frame 2 installation.
[0037] The working principle of this equipment management and monitoring device will be explained in detail below.
[0038] like Figure 1-5 As shown, the data processing module converts the analog signal input from the sensor into a digital signal, and performs filtering, amplification, and other processing on the digital signal. Simultaneously, it determines whether the experimental equipment is in normal operating condition based on a preset threshold. The monitoring module monitors the data of the experimental equipment and provides real-time warnings. The monitoring equipment component 3 monitors the high temperature generated in real time, which is transferred to the assembly rack 2. Combined with electric drive, this causes the coolant inside the circulation pipe 25 to move, carrying away some of the heat, thus achieving water circulation heat exchange. Then, the heat dissipation copper fin assembly 273, with its fast thermal conductivity, rapidly conducts heat, and the permeability of the heat dissipation grille 271 facilitates ventilation and heat dissipation, accelerating water circulation. The heat dissipation efficiency is beneficial for the heat dissipation protection of the device. The assembly frame 2 is slidably connected to the inner side of the sliding frame 281 through the sliding groove 28. The support baffle 282 and the protective pad 283 are installed at the bottom of one end of the assembly frame 2. The softness of the protective pad 283 and the rubber pad increases the stability of the bottom support, which is conducive to the stable installation of the device and reduces the generation of noise. The assembly frame 2 slides into the inner side of the sliding frame 281, which facilitates the sliding installation of the installation mechanism and increases the convenience. The movable locking block 286 is locked inside the connecting groove 284, and then the movable locking pin 287 is locked at the rear end of the locking block 286 for limiting the installation mechanism, which is conducive to the stability of the installation of the assembly frame 2.
[0039] The present invention has been described in detail above. However, modifications or improvements can be made to it, which will be obvious to those skilled in the art. Therefore, any modifications or improvements that do not depart from the spirit of the present invention are within the protection scope of the present invention.
Claims
1. An equipment management and monitoring device, comprising an experimental equipment monitoring box (1), characterized in that: An assembly frame (2) is movably installed inside the experimental equipment monitoring box (1). A monitoring equipment component (3) is fixedly installed on the top of the assembly frame (2). A data processing module is fixedly installed inside the monitoring equipment component (3). A monitoring module is fixedly connected to the side of the data processing module. A monitoring display screen (4) is fixedly installed on the top of the inner cavity of the experimental equipment monitoring box (1). A ventilation fan (5) is fixedly installed on the right side of the experimental equipment monitoring box (1). The assembly frame (2) has a disassembly groove (21) inside, and an installation plate (22) is detachably connected inside the disassembly groove (21). The surface of the installation plate (22) has a ventilation groove (23). The assembly frame (2) has grooves (28) on both sides, and a sliding frame (281) is movably installed inside the grooves (28). One end of the sliding frame (281) is fixedly installed on the inner wall of the experimental equipment monitoring box (1).
2. The equipment management and monitoring device according to claim 1, characterized in that: Heat sinks (24) are fixedly installed at both ends of the mounting plate (22), and a circulation pipe (25) is fixedly installed inside the heat sink (24). One end of the circulation pipe (25) is fixedly connected to an inlet / outlet pipe (26).
3. The equipment management and monitoring device according to claim 2, characterized in that: A heat-conducting plate (27) is fixedly installed on the top of the heat sink (24), a heat dissipation grid plate (271) is fixedly installed inside the heat-conducting plate (27), a connecting plate (272) is fixedly installed on the top of the heat dissipation grid plate (271), and a heat dissipation copper fin assembly (273) is fixedly installed on the top of the connecting plate (272).
4. The equipment management and monitoring device according to claim 1, characterized in that: A support baffle (282) is fixedly installed on the inner side of the sliding frame (281), and a protective pad (283) is fixedly installed on the top of the support baffle (282).
5. The equipment management and monitoring device according to claim 4, characterized in that: A rubber pad is fixedly installed on the surface of the protective pad (283), and the top of the rubber pad is located at the bottom of the assembly frame (2).
6. The equipment management and monitoring device according to claim 1, characterized in that: The top of both ends of the assembly frame (2) is provided with a moving groove (285), a locking block (286) is movably installed inside the moving groove (285), and a locking pin (287) is movably installed on the inner wall of the moving groove (285).
7. The equipment management and monitoring device according to claim 1, characterized in that: The sliding frame (281) has connecting grooves (284) at both ends, and the interior of the connecting grooves (284) is movably connected to one end of the locking block (286).