Radio monitoring data intelligent analysis management platform

By setting up a dustproof air curtain and drive mechanism in the intelligent analysis and management platform for radio monitoring data, the problems of dust intake and insufficient heat dissipation efficiency of the fan cooling system were solved, achieving efficient and stable heat dissipation and reducing the risk of equipment failure.

CN122269601APending Publication Date: 2026-06-23SHENZHEN RADIO DETECTION TECH RES INST

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
SHENZHEN RADIO DETECTION TECH RES INST
Filing Date
2026-04-24
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

The existing intelligent analysis and management platform for radio monitoring data has a fan cooling system that is prone to drawing in dust during the exchange of hot and cold air, which can lead to equipment failure. Moreover, the cooling effect is poor when operating under high load, making it difficult to cool down quickly.

Method used

The top cover internal air duct and air outlet block form a dustproof air curtain. The angle of the air guide component is adjusted by the drive mechanism to achieve centralized heat dissipation. Under high load, the motor is triggered by the temperature sensor and controller to drive the air guide block to rotate and concentrate the air force to enhance cooling.

Benefits of technology

It effectively prevents dust from entering the cabinet, improves heat dissipation efficiency, ensures stable equipment operation, quickly reduces temperature under high load, and reduces equipment failure and maintenance costs.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention relates to the field of data analysis and management platform technology, specifically to an intelligent analysis and management platform for radio monitoring data. It includes a cabinet with a top cover, an internal support frame, and an internal mounting plate for mounting the core data management module. A fan is installed inside the top cover, and an air guide assembly is installed on the top of the cabinet to guide air into the cabinet. An air intake block is installed inside the top cover, located at the top of the fan's outlet. An air duct is formed inside the top cover, with an outlet block installed at the end of the duct. Airflow is diverted by the fan, passing through the air duct and outlet block to form a dust-proof air curtain. A temperature sensor-driven mechanism adjusts the angle of the air guide block to achieve centralized heat dissipation, addressing both dust blocking and high / low load cooling needs, thus solving the problems of dust accumulation and insufficient high-load cooling in traditional cabinet heat dissipation systems.
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Description

Technical Field

[0001] This invention relates to the field of data analysis and management platform technology, and more specifically, to an intelligent analysis and management platform for radio monitoring data. Background Technology

[0002] The intelligent analysis and management platform for radio monitoring data is the core hub of the radio monitoring system. It is used to centrally receive, store, parse, and analyze various types of radio monitoring data. It can realize functions such as signal identification, spectrum analysis, interference location, and data visualization. It provides key technical support for radio spectrum resource management, interference investigation, and emergency communication guarantee. It is widely used in broadcasting, communications, national defense, emergency management and other fields, and is an important infrastructure to ensure radio communication order and security.

[0003] Existing intelligent analysis and management platforms for radio monitoring data mostly adopt a rack-type structure. Core management modules (such as data processing servers, spectrum analysis modules, storage modules, etc.) are centrally installed in racks within the computer room. Since these modules generate a lot of heat when operating under high load, heat accumulation can lead to decreased module performance, unstable operation, or even hardware burnout. Therefore, a fan cooling system is usually configured inside the rack to accelerate the exchange of hot and cold air inside and outside the rack, remove internal heat, and maintain the normal operating temperature of the modules.

[0004] However, the core principle of fan cooling is to achieve heat exchange by using airflow. Dust and other particulate matter are inevitably present in the computer room environment. The negative pressure generated when the fan is working will draw outside air and dust into the cabinet. This drawn-in dust will adhere to the circuit boards, heat sinks, interfaces and other key components of the management module. Long-term accumulation will lead to short circuits on the circuit boards, poor contact of the interfaces, module failure, reduced equipment reliability, affected continuity of monitoring work and increased maintenance costs. Summary of the Invention

[0005] This invention provides an intelligent analysis and management platform for radio monitoring data, which forms a dust-proof air curtain through the internal air duct and air outlet block of the top cover, and achieves centralized heat dissipation by adjusting the angle of the air guide component with the drive mechanism, thereby solving the problems mentioned in the background art.

[0006] To achieve the above objectives, the intelligent analysis and management platform for radio monitoring data includes a cabinet, a top cover of which is fixedly installed on the top of the cabinet by bolts, a support frame welded inside the cabinet, and an installation plate installed inside the support frame. The installation plate is used to install the core data management module.

[0007] A fan is fixedly installed inside the top cover by a bracket, and an air inlet is opened at the front end of the top cover, in which a filter plate is installed.

[0008] In the above technical solution, the air guiding assembly is a structure that realizes uniform distribution or centralized guidance of cold air. It includes multiple front air guiding blocks that are rotatably installed at the front end of the top crossbeam of the support frame, multiple rear air guiding blocks that are installed at the rear end of the top crossbeam of the support frame, and multiple middle air guiding blocks that are fixedly installed at the middle end of the top crossbeam of the support frame. The middle air guiding blocks are located directly above the mounting plate. The front air guiding blocks, rear air guiding blocks and middle air guiding blocks are all evenly distributed along the length of the crossbeam.

[0009] To prevent dust from entering the top cover, an air-guiding block is welded inside the top cover. The air-guiding block is located at the top of the air outlet of the fan. An inner plate is fixedly installed inside the top cover. The inner plate is located on top of the fan and the filter plate, forming a closed air duct with the inner wall of the top cover. The air duct is distributed along the inner wall of the top cover. An air outlet block is rotatably installed at the end of the air inlet of the top cover via a rotating shaft. A rubber strip is installed between the end of the air outlet block away from the rotating shaft and the top cover.

[0010] Based on the above, if the data management module operates under high load and the heat generated continues to rise, the initial uniform air cooling system is insufficient to meet the rapid cooling requirements. Therefore, a drive mechanism is installed inside the cabinet. The drive mechanism includes a motor fixedly mounted on the outer wall of the cabinet via a motor mount, and a drive shaft rotatably mounted in the top crossbeam of the support frame via bearings. The drive shaft is located between multiple central air guide blocks. The output shaft of the motor passes through the cabinet and the support frame and is fixedly connected to the drive shaft via a coupling. When the motor starts, it can drive the drive shaft to rotate in both directions.

[0011] Gears are installed at both ends of the drive shaft, the front guide block, and the rear guide block. A drive block is slidably installed in the top crossbeam of the support frame. The drive block is a strip-shaped metal block with multiple sets of tooth grooves on its outer wall. The tooth grooves mesh with the corresponding gears. The gears of the drive shaft and the front guide block are located at the top of the drive block and mesh with each other. The gear of the rear guide block is located at the bottom of the drive block and meshes with each other, forming a synchronous transmission structure.

[0012] Furthermore, gears are installed at both ends of the rotating shaft of the air outlet block, and the gears mesh with the tooth grooves on the top of the drive block to achieve linkage.

[0013] As the drive block moves backward, the gear meshing causes the air outlet block to rotate clockwise around the shaft, simultaneously stretching the rubber strip so that the air outlet of the air outlet block faces the filter plate. The residual air that was originally used to form an air curtain is blown back into the interior of the top cover. This avoids the slight impact of the air curtain on the main air intake and can also generate a slight negative pressure during concentrated heat dissipation, increasing the amount of outside air entering and further improving the heat dissipation effect.

[0014] Compared with the prior art, the beneficial effects of the present invention are as follows: 1. By setting up an air intake block, air duct, and air outlet block, when the fan draws in air, part of the airflow is guided into the air duct to form a circulation, and then discharged obliquely downward through the air outlet block. A ring-shaped dustproof air curtain is built at the bottom of the air inlet. This air curtain can prevent dust in the computer room air from accumulating at the air inlet. Together with the HEPA filter plate at the air inlet, it achieves dual dust prevention through air curtain blocking and filter filtration, reducing the amount of dust drawn into the cabinet with the airflow. This solves the problems of dust accumulation, blockage of heat dissipation channels, corrosion of electronic components, and impact on equipment operation stability and service life caused by traditional fan cooling.

[0015] 2. By setting up a drive mechanism, in conjunction with the temperature sensor and controller, an intelligent linkage is formed. When the internal temperature of the cabinet exceeds the standard, the controller triggers the motor to start. The drive shaft drives the drive block to move horizontally through gear meshing, and then synchronously drives the front air guide block to rotate clockwise and the rear air guide block to rotate counterclockwise. This concentrates the originally vertically downward airflow to the core data management module on the mounting plate, realizing focused airflow to enhance cooling. At the same time, the drive block drives the air outlet block to rotate through gear linkage, closing the air curtain and returning the residual air to the inside of the top cover to help increase the airflow and quickly remove the large amount of heat generated by the high-load module. This solves the problem of insufficient cooling efficiency and heat accumulation in the traditional uniform heat dissipation mode when the equipment is running under high load. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall structure of the present invention; Figure 2 This is a schematic diagram of the internal structure of the cabinet of the present invention; Figure 3 This is a schematic diagram of the airflow in the initial state of the air guide assembly of the present invention; Figure 4 This is a schematic cross-sectional view of the top cover of the present invention; Figure 5 This is an enlarged structural schematic diagram of the air outlet block of the present invention; Figure 6 This is a schematic diagram of the airflow in the initial state of the air duct and air outlet block of the present invention; Figure 7 This is an enlarged structural schematic diagram of the driving mechanism of the present invention; Figure 8 This is a schematic diagram of the airflow when the drive mechanism of the present invention is turned on; Figure 9 for Figure 8 Enlarged structural diagram at point A in the middle.

[0017] The meanings of the labels in the diagram are as follows: 1. Cabinet; 2. Top cover; 21. Air intake block; 22. Inner panel; 23. Air outlet block; 24. Rubber strip; 25. Air duct; 3. Support frame; 4. Mounting plate; 5. Air guide assembly; 51. Front air guide block; 52. Rear air guide block; 53. Middle air guide block; 6. Fan; 7. Filter plate; 8. Drive mechanism; 81. Motor; 82. Drive shaft; 83. Drive block. Detailed Implementation

[0018] The technical solutions of this invention will now be clearly and completely described with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this invention, and not all of them. All other embodiments obtained by those skilled in the art based on the embodiments of this invention without creative effort are within the scope of protection of this invention.

[0019] Traditional intelligent analysis and management platforms for radio monitoring data often rely on rack-mounted fan cooling systems that draw in dust during hot and cold air exchange. This dust accumulation can impair heat dissipation, damage equipment, and result in poor uniform heat dissipation under high loads, hindering rapid cooling. Therefore, to address these issues, this invention provides an intelligent analysis and management platform for radio monitoring data, with the specific structure and implementation details as follows: refer to Figure 1-2 As shown, the cabinet includes a cabinet body 1. A top cover 2 is fixed to the top of the cabinet body 1 by bolts. A sealing gasket is provided between the top cover 2 and the cabinet body 1 to enhance the sealing performance and reduce dust from entering through gaps. A support frame 3 is welded inside the cabinet body 1. The support frame 3 is a metal frame structure to ensure stability. An mounting plate 4 is movably installed inside the support frame 3 via a slide rail. The mounting plate 4 is an anti-static metal plate used to install core data management modules such as data processing servers, spectrum analysis modules, and storage modules. The slide rail design facilitates the disassembly, assembly, and maintenance of the modules.

[0020] A fan 6 is fixedly installed inside the top cover 2 by a bracket. The fan 6 is a high-pressure, low-noise axial fan, which ensures heat dissipation efficiency while reducing operating noise. An air inlet is opened at the front end of the top cover 2. A filter plate 7 is fixedly installed in the air inlet by bolts. The filter plate 7 can filter fine dust and particulate matter in the air. The fan 6 is vertically distributed with the filter plate 7 to ensure that all the air drawn in passes through the filter plate 7.

[0021] When the temperature inside the cabinet 1 rises, the fan 6 starts, creating a negative pressure inside the top cover 2. This draws in cool air from the outside through the air inlet. The air is first filtered by the filter plate 7, removing most of the dust and impurities before entering the top cover 2. As the air pressure inside the top cover 2 increases, the filtered cool air is guided by the air guide component 5 and evenly enters the cabinet 1. It then exchanges heat with the hot air generated by the core module. The hot air after the heat exchange is discharged from the heat dissipation holes (not shown in the figure) on the rear side of the cabinet 1, forming a complete air circulation. This cools the inside of the cabinet 1 and maintains the module operating at a suitable temperature.

[0022] Among them, reference Figure 3 As shown by the dashed line representing the airflow, the air guide assembly 5 is a structure that achieves uniform distribution or concentrated guidance of cold air. It includes multiple front air guide blocks 51 that are rotatably installed at the front end of the top crossbeam of the support frame 3, multiple rear air guide blocks 52 that are installed at the rear end of the top crossbeam of the support frame 3, and multiple middle air guide blocks 53 that are fixedly installed at the middle end of the top crossbeam of the support frame 3. The middle air guide blocks 53 are located directly above the mounting plate 4, and the front air guide blocks 51, rear air guide blocks 52 and middle air guide blocks 53 are all evenly distributed along the length of the crossbeam.

[0023] In the initial state, the front air guide block 51, the rear air guide block 52, and the middle air guide block 53 are all in a vertical position. At this time, as the cold air in the top cover 2 enters the cabinet 1, the airflow is guided by the front air guide block 51, the rear air guide block 52, and the middle air guide block 53, so that the airflow direction is vertically downward and uniformly flows. The cold air fully covers the inside of the cabinet 1 from top to bottom, realizing uniform heat dissipation of each module.

[0024] To prevent dust from entering the top cover 2, refer to... Figure 4-5 As shown, an air-guiding block 21 is welded inside the top cover 2. The air-guiding block 21 is located at the top of the air outlet of the fan 6 and is used to divert part of the airflow blown out by the fan 6 to the air duct 25. An inner plate 22 is fixedly installed inside the top cover 2. The inner plate 22 is located on top of the fan 6 and the filter plate 7 and forms a closed air duct 25 with the inner wall of the top cover 2. The air duct 25 is distributed along the inner wall of the top cover 2 to ensure smooth flow of the diverted airflow. An air outlet block 23 is rotatably installed at the end of the air inlet of the top cover 2 via a rotating shaft. It corresponds to the air inlet and can rotate flexibly around the rotating shaft. A rubber strip 24 is installed between the end of the air outlet block 23 away from the rotating shaft and the top cover 2. The rubber strip 24 is made of elastic material and is used for the reset and sealing of the air outlet block 23 to prevent the undiverted airflow from leaking from the gap.

[0025] For detailed procedures, please refer to [link / reference] Figure 6 As shown by the dashed line representing the airflow, when air is drawn into the top cover 2 by the fan 6, a portion of the airflow at the top of the fan 6 outlet is diverted into the air duct 25 by the air guide block 21. The airflow flows in the air duct 25 and is eventually discharged obliquely downward from each air outlet block 23, forming an annular air curtain.

[0026] The air curtain is located at the bottom of the air inlet, which covers the connection between the air inlet and cabinet 1. It can effectively prevent dust in the air of the computer room from accumulating near the air inlet and prevent dust from being sucked into the cabinet with the main airflow.

[0027] It should be noted that the airflow required by the air curtain accounts for only a small portion of the total airflow of the fan, which can be achieved by utilizing the residual airflow. It has no significant negative impact on the airflow, air pressure, and internal heat dissipation efficiency of the main air intake, and does not affect the core heat dissipation function while blocking dust.

[0028] If the data management module operates under high load, the heat generated will continue to rise. The initial uniform air cooling system will be unable to meet the rapid cooling requirements. Therefore, a drive mechanism 8 is installed inside the cabinet 1 to drive the angle of each air guide block in the air guide assembly 5, thereby achieving concentrated airflow to enhance cooling. At the same time, a temperature sensor and a controller (not shown in the figure) are installed inside the cabinet 1. The temperature sensor is used to monitor the internal temperature of the cabinet 1 in real time, and the controller is used to receive the temperature signal and control the operating status of the drive mechanism 8 and the fan 6 to achieve intelligent heat dissipation regulation.

[0029] For details, please refer to the following: Figure 7 As shown, the drive mechanism 8 includes a motor 81 fixedly mounted on the outer wall of the cabinet 1 via a motor mount. The motor 81 is a servo motor with precise and controllable speed, providing power for angle adjustment. A drive shaft 82 is rotatably mounted in the top crossbeam of the support frame 3 via a bearing. The drive shaft 82 is located between multiple central air guide blocks 53. The output shaft of the motor 81 passes through the cabinet 1 and the support frame 3 and is fixedly connected to the drive shaft 82 via a coupling. When the motor 81 starts, it can drive the drive shaft 82 to rotate in both directions.

[0030] Gears are installed at both ends of the drive shaft 82, the front guide block 51, and the rear guide block 52. A drive block 83 is slidably installed in the top crossbeam of the support frame 3. The drive block 83 is a strip-shaped metal block with multiple sets of tooth grooves on its outer wall. The tooth grooves mesh with the corresponding gears. The gears of the drive shaft 82 and the front guide block 51 are located at the top of the drive block 83 and mesh with each other. The gear of the rear guide block 52 is located at the bottom of the drive block 83 and meshes with each other, forming a synchronous transmission structure.

[0031] For details, please refer to the following: Figure 8As indicated by the dashed line representing the airflow, when the data management module heats up and the temperature sensor detects that the internal temperature of cabinet 1 exceeds the preset threshold, the sensor transmits a signal to the controller. The controller then controls motor 81 to start, driving drive shaft 82 to rotate clockwise. Drive shaft 82 drives drive block 83 to move backward through gear meshing. During the backward movement of drive block 83, the top tooth groove meshes with the gear of front air guide block 51, driving front air guide block 51 to rotate clockwise to an inclined state, so that the airflow is tilted towards the module at the front end of mounting plate 4. At the same time, through the bottom tooth groove meshing with the gear of rear air guide block 52, the rear air guide block 52 is driven to rotate counterclockwise to an inclined state, so that the airflow is tilted towards the module at the rear end of mounting plate 4. Meanwhile, the middle air guide block 53 maintains a constant vertical angle, continuously guiding cold air vertically downward towards the module in the middle of mounting plate 4. This ensures that most of the cold air entering from top cover 2 is concentrated and guided to the surface of the core module on mounting plate 4 when passing through air guide assembly 5, achieving concentrated airflow for rapid cooling and significantly improving heat dissipation efficiency.

[0032] Furthermore, gears are installed at both ends of the rotating shaft of the air outlet block 23, and these gears mesh with the tooth grooves on the top of the drive block 83 to achieve linkage.

[0033] refer to Figure 9 As shown, when the drive block 83 moves backward, it drives the air outlet block 23 to rotate clockwise around the shaft through gear meshing, while simultaneously stretching the rubber strip 24, so that the air outlet of the air outlet block 23 faces the filter plate 7. The residual air originally used to form an air curtain is blown back into the interior of the top cover 2. This avoids the slight impact of the air curtain on the main air intake, and can also generate a slight negative pressure during concentrated heat dissipation, increasing the amount of outside air entering and further improving the heat dissipation effect.

[0034] It should be noted that the air curtain disappears temporarily at this time, but due to the increased air volume and concentrated air direction, the internal temperature of cabinet 1 can be quickly reduced in a short time. When the temperature sensor detects that the temperature has dropped to the preset safe value, the controller controls the motor 81 to reverse, drive all components to return to their original positions, the rubber strip 24 pulls the air outlet block 23 to reset, the air curtain is formed again, and the dust blocking function is restored.

[0035] It should be noted that although the air curtain disappears at this time, the air volume increases and the wind direction becomes concentrated, which can quickly cool down the air. After cooling down, the components return to their original positions and the air curtain will reappear.

[0036] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely preferred examples and are not intended to limit the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of the present invention is defined by the appended claims and their equivalents.

Claims

1. A radio monitoring data intelligent analysis and management platform, comprising a cabinet (1), characterized in that: The cabinet (1) is equipped with a top cover (2), a support frame (3) is installed inside the cabinet (1), an installation plate (4) is installed inside the support frame (3), the installation plate (4) is used to install the core data management module, a fan (6) is installed inside the top cover (2), an air inlet is opened on the top cover (2), and a filter plate (7) is installed in the air inlet. The top of the cabinet (1) is equipped with an air guide assembly (5), which is used to guide air into the cabinet (1). The cabinet (1) is equipped with a drive mechanism (8) to drive the angle of the air guide assembly (5). An air-guiding block (21) is installed inside the top cover (2). The air-guiding block (21) is located at the top of the air outlet of the fan (6). An air duct (25) is provided inside the top cover (2). An air outlet block (23) is installed at the end of the air duct (25).

2. The intelligent analysis and management platform for radio monitoring data according to claim 1, characterized in that: An inner plate (22) is installed inside the top cover (2). The inner plate (22) is located on top of the fan (6) and the filter plate (7). An air duct (25) is formed between the top cover (2) and the inner plate (22).

3. The intelligent analysis and management platform for radio monitoring data according to claim 1, characterized in that: The air guide assembly (5) includes a plurality of front air guide blocks (51) rotatably mounted on the front end of the top beam of the support frame (3), a plurality of rear air guide blocks (52) mounted on the rear end of the top beam of the support frame (3), and a plurality of middle air guide blocks (53) fixedly mounted on the middle end of the top beam of the support frame (3). The middle air guide blocks (53) are located on the top of the mounting plate (4).

4. The intelligent analysis and management platform for radio monitoring data according to claim 3, characterized in that: The drive mechanism (8) includes a drive shaft (82) rotatably mounted in the top crossbeam of the support frame (3), the drive shaft (82) being located between a plurality of intermediate air guide blocks (53).

5. The intelligent analysis and management platform for radio monitoring data according to claim 1, characterized in that: A motor (81) is installed on the outer wall of the cabinet (1). The output shaft of the motor (81) passes through the cabinet (1) and the support frame (3) and is connected to the drive shaft (82).

6. The intelligent analysis and management platform for radio monitoring data according to claim 4, characterized in that: Gears are installed at both ends of the drive shaft (82), the front air guide block (51) and the rear air guide block (52). A drive block (83) is slidably installed in the top crossbeam of the support frame (3). The outer wall of the drive block (83) is provided with multiple sets of tooth grooves.

7. The intelligent analysis and management platform for radio monitoring data according to claim 6, characterized in that: The gears of the drive shaft (82) and the front guide block (51) are located on top of the drive block (83) and mesh with each other.

8. The intelligent analysis and management platform for radio monitoring data according to claim 6, characterized in that: The gear of the rear air guide block (52) is located at the bottom of the drive block (83) and meshes with each other.

9. The intelligent analysis and management platform for radio monitoring data according to claim 1, characterized in that: The air outlet block (23) is installed at the end of the air outlet block (23) via a rotating shaft. Gears are installed at both ends of the rotating shaft and mesh with each other at the top of the drive block (83).

10. The intelligent analysis and management platform for radio monitoring data according to claim 1, characterized in that: A rubber strip (24) is installed between the end of the air outlet block (23) away from the rotating shaft and the top cover (2) for resetting and sealing the air outlet block (23).