A network data real-time monitoring device based on next-generation information network

By combining shape memory alloy springs and elastic copper sheets, the clamping force of the connector is automatically adjusted to maintain a stable connection. The heat sink and air circulation are used for cooling, which solves the problem of loosening and interruption caused by overheating of the connector, thus achieving stable information transmission and extending the equipment life.

CN122246529APending Publication Date: 2026-06-19HENGYANG LIANGDA INFORMATION TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
HENGYANG LIANGDA INFORMATION TECHNOLOGY CO LTD
Filing Date
2026-04-22
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In next-generation information networks, connectors may overheat due to continuous data transmission, leading to reduced insertion and extraction force and loosening of the contact interface, which could cause communication link interruption.

Method used

It employs a combination of shape memory alloy springs and elastic copper sheets to automatically adjust the clamping force of the connector to maintain a tight fit; combined with heat dissipation fins and air circulation, it actively dissipates heat through heat conduction and convection.

Benefits of technology

Maintain connection stability in high-temperature environments to prevent loosening and detachment, while effectively reducing connector temperature to ensure continuous stability of information transmission and extend equipment lifespan.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention discloses a real-time network data monitoring device based on a next-generation information network, belonging to the technical field of real-time network data monitoring devices. The device includes a housing, inside which a monitoring device is detachably installed. When the connector is in a long-term information transmission state, the internal impedance and current flow cause the temperature to gradually rise. At this time, a shape memory alloy spring located inside the connector socket deforms due to temperature sensing, driving a pressing roller to automatically move towards the top of the connector and apply a stable compressive force. This mechanism ensures that even if the connector undergoes slight thermal deformation in a high-temperature environment, it maintains a tight connection with the connector socket, preventing signal interruption or accidental connector detachment due to loose contact interface.
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Description

Technical Field

[0001] This invention relates to the field of network data real-time monitoring device technology, specifically a network data real-time monitoring device based on next-generation information networks. Background Technology

[0002] Traditional network monitoring technologies are mostly based on simple network management protocols or fixed-period polling mechanisms, with data acquisition granularity at the minute level and high coupling between the control plane and data plane. In next-generation information network architectures such as software-defined networking and information-centric networks, networks exhibit characteristics of high-speed forwarding, dynamic topology, and fusion of multi-source heterogeneous data.

[0003] When monitoring equipment is in operation for extended periods, the connector inserted into the connection socket experiences a significant temperature rise due to continuous data transmission. Overheating of the connector not only reduces the insertion and extraction force between it and the connection socket but also causes the contact interface to loosen due to thermal deformation. If the connector partially or completely detaches from the connection socket due to overheating, it will directly cause a communication link interruption, resulting in the inability to transmit information. In view of this, we propose a real-time network data monitoring device based on a next-generation information network. Summary of the Invention

[0004] To address the shortcomings of existing technologies, this invention provides a real-time network data monitoring device based on next-generation information networks, which solves the problems mentioned in the background section.

[0005] To achieve the above objectives, the present invention is implemented through the following technical solution: a real-time network data monitoring device based on a next-generation information network, comprising: a housing, wherein a monitoring device is detachably installed inside the housing, a connection socket is fixed at the bottom of the monitoring device, a connector is inserted into the connection socket, heat dissipation holes are provided on the outer wall of the housing, and a fixing cover is fixed at the bottom of the monitoring device; An elastic copper sheet, one side of which is fixed inside the fixing cover, and the other side of which is attached to the outer wall of the connector, is used to press the connector together. A copper rod, the end of which is fixed to the outer wall of an elastic copper sheet, and the copper rod passes through the side wall of the fixed cover, with a sliding connection at the point of penetration; A sealing cover is fixed to the side wall of a fixed cover, and the end of a copper rod passes through the sealing cover and is slidably connected at the point of penetration; Piston plate, which is slidably mounted inside the sealing cover; A shape memory alloy spring, one side of which is fixed to the inner wall of a sealing cover, and the other side of which is fixed to the side wall of a piston plate; A push rod is fixed to the side of the piston plate away from the shape memory alloy spring, and a bending block is fixed to the end of the push rod away from the piston plate. A hinge seat is fixed to the bottom of a fixed cover. A rotating rod is rotatably mounted on the inner side of the hinge seat. A rotating block is fixed to the outer wall of the rotating rod. A clamping roller is fixed to the inner side of the rotating block. The clamping roller is used to prevent the connector from disengaging from the connector socket.

[0006] According to the above technical solution, a connecting spring is fixed to the side wall of the piston plate, and the side of the connecting spring away from the piston plate is fixed to the inner wall of the sealing cover.

[0007] According to the above technical solution, a protrusion is fixed on the outer wall of the rotating rod. When the upper half of the protrusion is squeezed by the end of the bending block, it can drive the rotating rod and the rotating block to rotate.

[0008] According to the above technical solution, a cooling device is provided on the fixing cover, which is used to cool the connector; a limit device is provided on the cooling device.

[0009] According to the above technical solution, the cooling device includes: a sliding frame, which is slidably mounted on the outer wall of the fixed cover; An extrusion rod, which is fixed to the top of the sliding frame; A sliding plate extends through a fixed cover and is slidably connected at the point of penetration. Heat dissipation fins are attached to the inside of the sliding plate to dissipate heat from the connector.

[0010] According to the above technical solution, the bottom of the sliding plate is provided with an inclined groove, the end of the extrusion rod is fitted with the inside of the inclined groove, a return spring is fixed at the end protrusion of the heat dissipation fin, the end of the return spring is fixed at the outer wall protrusion of the sliding plate, and an air inlet is provided at the bottom of the outer shell, the air inlet is used to remove the heat from the heat dissipation fin.

[0011] According to the above technical solution, the limiting device includes: an elastic sheet, the end of which is fixed to the outer wall of the fixing cover; A fixing block, which is fixed to the inside of the sliding frame; A guide block is fixed to the outer wall of the fixed cover, and a limit hole is formed on the top of the guide block.

[0012] According to the above technical solution, a limiting rod passes through the fixing block and fits snugly at the penetration point. The cooperation between the limiting rod and the limiting hole is used to fix the heat dissipation fins. A handle is fixed to the top of the limiting rod, and a return spring is fixed to the bottom of the handle. The bottom of the return spring is fixed to the top of the fixing block.

[0013] This invention provides a real-time network data monitoring device based on next-generation information networks. It has the following beneficial effects: 1. When the connector is in a long-term information transmission state, the internal impedance and current flow cause the temperature to gradually rise. At this time, the shape memory alloy spring set in the connector socket will deform due to temperature sensing, driving the clamping roller to automatically move towards the top of the connector and apply a stable pressing force. This ensures that even if the connector undergoes slight thermal deformation in a high-temperature environment, it can still maintain a tight connection with the connector socket, avoiding signal interruption or accidental detachment of the connector due to loose contact interface. At the same time, when the connector is first inserted into the connector socket, its sidewall will squeeze the elastic copper sheet, causing the elastic copper sheet to compress and deform. The elastic copper sheet then applies a reaction force to the connector, forming a stable radial clamp, effectively resisting the mechanical vibration generated during equipment operation, preventing the connector from gradually loosening due to vibration, thereby ensuring the continuous stability of information transmission.

[0014] 2. To further address the overheating problem of the connector, this invention also includes a sliding frame, a pressing rod, a sliding plate, an inclined groove, and heat dissipation fins. When the connector temperature rises, the heat dissipation fins automatically move towards and contact the outer wall of the connector, absorbing the heat accumulated on the connector surface through heat conduction, thus playing a role in active heat dissipation and preventing local overheating that could lead to aging of the connector material or degradation of electrical performance. Simultaneously, with the assistance of the connecting spring, the ends of the heat dissipation fins can continuously apply elastic pressure, keeping them in close contact with the outer wall of the connector, significantly improving heat exchange efficiency. Furthermore, an air inlet is provided at the top of the housing, allowing outside cold air to enter the housing. Due to the higher density of cold air, it naturally sinks, while heated air rises, thus forming an upward convection path inside the housing. This carries away the heat absorbed by the heat dissipation fins and discharges it through the heat dissipation holes on the housing, achieving air circulation cooling.

[0015] 3. When the heat dissipation fins and the connector are in contact, the present invention uses a locking mechanism consisting of a fixing block, a guide block, a limiting rod, a return spring, and a limiting hole to fix the position of the heat dissipation fins. This ensures that the heat dissipation fins can be stably attached to the connector and continuously perform heat dissipation. It also prevents the heat dissipation fins from moving back and forth frequently due to temperature fluctuations in the connector, which could affect the heat dissipation effect or accelerate the wear of the mechanism. When it is necessary to remove the connector, the operator can pull the handle to move the limiting rod out of the limiting hole, releasing the limitation on the heat dissipation fins. The elastic sheet then causes the heat dissipation fins to automatically retract and detach from the outer wall of the connector, thereby eliminating insertion and removal resistance and facilitating the smooth removal of the connector. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall structure of the present invention; Figure 2This is a schematic diagram of the internal structure of the housing of the present invention; Figure 3 This is a partial structural diagram of the present invention; Figure 4 This is a partial cross-sectional view of the present invention; Figure 5 This is a partial structural diagram of the present invention; Figure 6 This is a schematic diagram of the internal structure of the sealing cover of the present invention; Figure 7 This is a schematic diagram of the cooling device of the present invention; Figure 8 This is a schematic diagram of the limiting device structure of the present invention.

[0017] In the diagram: 1. Housing; 2. Monitoring equipment; 3. Heat dissipation hole; 4. Connection socket; 5. Connector; 6. Fixing cover; 7. Elastic copper sheet; 8. Copper rod; 9. Sealing cover; 10. Shape memory alloy spring; 11. Piston plate; 12. Connecting spring; 13. Push rod; 14. Bending block; 15. Hinge seat; 16. Rotating rod; 17. Rotating block; 18. Protrusion; 19. Pressing roller; 201. Sliding frame; 202. Extrusion rod; 203. Sliding plate; 204. Inclined groove; 205. Heat dissipation fins; 206. Return spring; 207. Air inlet; 301. Elastic sheet; 302. Fixing block; 303. Guide block; 304. Limiting rod; 305. Return spring; 306. Handle; 307. Limiting hole. Detailed Implementation

[0018] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0019] Please see Figures 1-8 One embodiment of the present invention is: a network data real-time monitoring device based on a next-generation information network, comprising: a housing 1, a monitoring device 2 detachably installed inside the housing 1, a connection socket 4 fixed at the bottom of the monitoring device 2, a connector 5 inserted into the connection socket 4, heat dissipation holes 3 on the outer wall of the housing 1, and a fixing cover 6 fixed at the bottom of the monitoring device 2. The elastic copper sheet 7 is fixed inside the fixing cover 6 on one side and attached to the outer wall of the connector 5 on the other side to press the connector 5. Copper rod 8, the end of copper rod 8 is fixed to the outer wall of elastic copper sheet 7, and copper rod 8 penetrates the side wall of fixed cover 6, with sliding connection at the penetration point; The sealing cover 9 is fixed to the side wall of the fixed cover 6, and the end of the copper rod 8 passes through the sealing cover 9 and is slidably connected at the penetration point. Piston plate 11, which is slidably mounted inside the sealing cover 9; A shape memory alloy spring 10 is fixed on one side to the inner wall of the sealing cover 9 and on the other side to the side wall of the piston plate 11. Push rod 13 is fixed on the side of piston plate 11 away from shape memory alloy spring 10, and a bending block 14 is fixed at the end of push rod 13 away from piston plate 11. A hinge seat 15 is fixed to the bottom of the fixed cover 6. A rotating rod 16 is rotatably mounted on the inner side of the hinge seat 15. A rotating block 17 is fixed to the outer wall of the rotating rod 16. A pressing roller 19 is fixed to the inner side of the rotating block 17. The pressing roller 19 is used to prevent the connector 5 from disengaging from the connecting hole 4. A connecting spring 12 is fixed to the side wall of the piston plate 11. The side of the connecting spring 12 away from the piston plate 11 is fixed to the inner wall of the sealing cover 9. A protrusion 18 is fixed to the outer wall of the rotating rod 16. When the upper half of the protrusion 18 is squeezed by the end of the bending block 14, it can drive the rotating rod 16 and the rotating block 17 to rotate.

[0020] When connector 5 is in information transmission mode for a long time, its internal impedance and current flow will cause the temperature to gradually rise. At this time, the shape memory alloy spring 10 installed in the connector 4 will deform due to temperature sensing, driving the clamping roller 19 to move automatically towards the top of connector 5 and apply a stable pressing force; Ensure that even if the connector 5 undergoes slight thermal deformation in a high-temperature environment, it can still maintain a tight connection with the connector 4, and avoid signal interruption or accidental detachment of the connector 5 due to loose contact interface.

[0021] At the same time, when the connector 5 is first inserted into the connector socket 4, its side wall will squeeze the elastic copper sheet 7, causing the elastic copper sheet 7 to compress and deform. The elastic copper sheet 7 then applies a reaction force to the connector 5, forming a stable radial clamp, which effectively resists the mechanical vibration generated during equipment operation and prevents the connector 5 from gradually loosening due to vibration, thereby ensuring the continuous stability of information transmission.

[0022] In this embodiment, when connector 5 is inserted into the connection socket 4 of monitoring device 2 for information transmission, the outer wall of connector 5 will compress the outer wall of elastic copper sheet 7, causing elastic copper sheet 7 to deform and adhere to the outer wall of connector 5. Connector 5 inevitably generates a large amount of heat during long-term operation. Elastic copper sheet 7 transfers the heat to copper rod 8, which then conducts the heat to the sealing cover 9. Shape memory alloy spring 10 deforms due to temperature sensing, increasing its force, thereby pressing piston plate 11 to move away from fixed cover 6 within sealing cover 9. Piston plate 11 simultaneously compresses connecting spring 12. When piston plate 11 moves, it drives push rod 13 to move out of sealing cover 9. Push rod 13 drives bending block 14 to move, bending block 14 compresses protrusion 18, causing protrusion 18 to rotate under force, driving rotating rod 16 to rotate. Rotating rod 16 drives rotating block 17 to rotate upwards, causing pressing roller 19 to press against the bottom of connector 5, thus ensuring a stable connection between connector 5 and connection socket 4.

[0023] When the temperature of connector 5 decreases, the temperature transmitted to the elastic copper sheet 7 and sealing cover 9 also decreases. The shape memory alloy spring 10 returns to its original shape due to the temperature drop, and its force decreases. At this time, the compressed connecting spring 12 drives the piston plate 11 to reset, and the piston plate 11 drives the push rod 13 and bending block 14 to reset. The bending block 14 no longer presses against the protrusion 18. The clamping roller 19 automatically rotates downwards to return to its original position due to gravity, avoiding damage caused by prolonged pressure on the bottom of connector 5 and reducing its service life.

[0024] Please see Figures 1-8 Based on the above embodiments, in another embodiment of the present invention, a cooling device is provided on the fixing cover 6 for cooling the connector 5; The cooling device includes: a sliding frame 201, which is slidably mounted on the outer wall of the fixed cover 6; The extrusion rod 202 is fixed to the top of the sliding frame 201; A sliding plate 203 and a pressing rod 202 pass through the fixed cover 6 and are slidably connected at the passage. A heat dissipation fin 205 is attached to the inside of the sliding plate 203. The heat dissipation fin 205 is used to absorb the heat on the connector 5. A sloping groove 204 is opened at the bottom of the sliding plate 203. The end of the pressing rod 202 is attached to the inside of the sloping groove 204. A return spring 206 is fixed at the protruding end of the heat dissipation fin 205. The end of the return spring 206 is fixed at the protruding part of the outer wall of the sliding plate 203. An air inlet 207 is opened at the bottom of the housing 1. The air inlet 207 is used to carry away the heat from the heat dissipation fin 205.

[0025] To further address the overheating issue of connector 5, a sliding frame 201, a pressing rod 202, a sliding plate 203, a slanted groove 204, and heat dissipation fins 205 are also included. When the temperature of connector 5 rises, the heat dissipation fins 205 automatically move towards and contact the outer wall of connector 5, absorbing the heat accumulated on the surface of connector 5 through heat conduction, thus playing an active heat dissipation role and preventing local overheating that could lead to material aging or deterioration of electrical performance of connector 5. Simultaneously, with the cooperation of the return spring 206, the ends of the heat dissipation fins 205 can continuously apply elastic pressure, keeping them in close contact with the outer wall of connector 5, significantly improving heat exchange efficiency.

[0026] In addition, an air inlet 207 is provided at the bottom of the housing 1, through which cold air from the outside can enter the interior of the housing 1. Since cold air has a higher density and naturally sinks, while heated air rises, a convection path from bottom to top is formed inside the housing 1, which carries away the heat absorbed by the heat dissipation fins 205 and discharges it through the heat dissipation holes 3 on the housing 1, thereby achieving air circulation and cooling.

[0027] The cooling device is equipped with a limiting device, which includes an elastic sheet 301, the end of which is fixed to the outer wall of the fixing cover 6. Fixing block 302 is fixed to the inner side of sliding frame 201; The guide block 303 and the fixing block 302 are fixed to the outer wall of the fixing cover 6. The top of the guide block 303 has a limiting hole 307. The fixing block 302 has a limiting rod 304 passing through it and fitting snugly at the point of penetration. The limiting rod 304 and the limiting hole 307 are used to fix the heat dissipation fins 205. The top of the limiting rod 304 is fixed with a handle 306, and the bottom of the handle 306 is fixed with a return spring 305. The bottom of the return spring 305 is fixed to the top of the fixing block 302.

[0028] When the heat dissipation fins 205 and the connector 5 are in contact, the position of the heat dissipation fins 205 is fixed by the locking mechanism consisting of the fixing block 302, the guide block 303, the limiting rod 304, the return spring 305 and the limiting hole 307. This ensures that the heat dissipation fins 205 can be stably attached to the connector 5 and continue to perform heat dissipation. It also prevents the heat dissipation fins 205 from moving back and forth frequently due to temperature fluctuations in the connector 5, which would affect the heat dissipation effect or accelerate the wear of the mechanism.

[0029] When it is necessary to remove the connector 5, the operator can pull the handle 306 to drive the limit rod 304 out of the limit hole 307, thereby releasing the limit on the heat sink fin 205. The elastic sheet 301 will cause the heat sink fin 205 to automatically retract and detach from the outer wall of the connector 5, thereby eliminating the insertion and removal resistance and making it easy to remove the connector 5 smoothly.

[0030] In this embodiment, when the push rod 13 moves outward from the sealing cover 9, the bending block 14 presses against the sliding frame 201, causing the sliding frame 201 to move on the outer wall of the fixed cover 6. As the sliding frame 201 moves, it drives the pressing rod 202 to move. The pressing rod 202 moves in the inclined groove 204 and presses against the inclined groove 204, causing the sliding plate 203 to move within the fixed cover 6 under pressure. This causes the heat dissipation fins 205 to contact the outer wall of the connector 5, dissipating heat from the connector 5. When the heat dissipation fins 205 contact the connector 5, the sliding plate 203 continues to move, causing the heat dissipation fins 205 to move within the sliding plate 203. The return spring 206 is stretched, and the return spring 206 provides a reaction force to the heat dissipation fins 205, causing the heat dissipation fins 205 to fit tightly against the outer wall of the connector 5. When the heat dissipation fins 205 absorb heat from the connector 5, cold air from the outside enters the housing 1 through the air inlet 207, comes into contact with the heat dissipation fins 205, and carries away the heat from the heat dissipation fins 205.

[0031] When the sliding frame 201 moves, the fixing block 302 moves on the guide block 303, causing the elastic sheet 301 to stretch and deform. When the fixing block 302 moves to the point where the limiting rod 304 aligns with the limiting hole 307 on the guide block 303, the return spring 305 is in a stretched state, which will cause the handle 306 and the limiting rod 304 to move downward, so that the limiting rod 304 is inserted into the limiting hole 307, fixing the fixing block 302, thereby fixing the sliding frame 201. The heat dissipation fins 205 remain in contact with the outer wall of the connector 5, effectively performing heat dissipation.

[0032] When heat dissipation of connector 5 is not required, simply pull handle 306 to move limit rod 304 out of limit hole 307, releasing the limit on fixing block 302. Since elastic sheet 301 is in a stretched deformation state, it will drive fixing block 302 to reset. Fixing block 302 will drive sliding frame 201 to reset. Sliding frame 201 will drive pressing rod 202 to reset in inclined groove 204. Pressing rod 202 will press inclined groove 204, causing sliding plate 203 to move out of fixing cover 6, thereby moving heat dissipation fins 205 away from connector 5 and resetting.

[0033] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A real-time network data monitoring device based on a next-generation information network, characterized in that, include: The housing (1) has a monitoring device (2) that can be detachably installed inside. The bottom of the monitoring device (2) is fixed with a connection socket (4). A connector (5) is inserted into the connection socket (4). The outer wall of the housing (1) has heat dissipation holes (3). The bottom of the monitoring device (2) is fixed with a fixing cover (6). Elastic copper sheet (7), one side of which is fixed inside the fixing cover (6), and the other side of which is attached to the outer wall of the connector (5). The elastic copper sheet (7) is used to press the connector (5). A copper rod (8) has its end point fixed to the outer wall of an elastic copper sheet (7), and the copper rod (8) passes through the side wall of the fixed cover (6), with a sliding connection at the point of penetration; A sealing cover (9) is fixed to the side wall of a fixed cover (6), and the end of a copper rod (8) passes through the sealing cover (9) and is slidably connected at the point of penetration. Piston plate (11), which is slidably mounted inside the sealing cover (9); A shape memory alloy spring (10) is fixed on one side of the sealing cover (9) and on the other side of the piston plate (11). Push rod (13), the push rod (13) is fixed on the side of piston plate (11) away from shape memory alloy spring (10), and a bending block (14) is fixed at the end of the push rod (13) away from piston plate (11). A hinge seat (15) is fixed to the bottom of a fixed cover (6). A rotating rod (16) is rotatably mounted on the inner side of the hinge seat (15). A rotating block (17) is fixed on the outer wall of the rotating rod (16). A pressing roller (19) is fixed on the inner side of the rotating block (17). The pressing roller (19) is used to prevent the connector (5) from disengaging from the connector socket (4).

2. The network data real-time monitoring device based on next-generation information networks according to claim 1, characterized in that, A connecting spring (12) is fixed to the side wall of the piston plate (11), and the side of the connecting spring (12) away from the piston plate (11) is fixed to the inner wall of the sealing cover (9).

3. The network data real-time monitoring device based on next-generation information networks according to claim 2, characterized in that, The outer wall of the rotating rod (16) is fixed with a protrusion (18). When the upper part of the protrusion (18) is squeezed by the end of the bending block (14), it can drive the rotating rod (16) and the rotating block (17) to rotate.

4. The network data real-time monitoring device based on next-generation information networks according to claim 3, characterized in that, A cooling device is provided on the fixed cover (6), which is used to cool the connector (5); a limit device is provided on the cooling device.

5. A real-time network data monitoring device based on a next-generation information network according to claim 4, characterized in that, The cooling device includes: a sliding frame (201), which is slidably mounted on the outer wall of the fixed cover (6); A compression rod (202) is fixed to the top of the sliding frame (201); A sliding plate (203) is inserted through the fixed cover (6) and slidably connected at the insertion point. Heat dissipation fins (205) are attached inside the sliding plate (203) and are used to dissipate heat from the connector (5).

6. The network data real-time monitoring device based on next-generation information networks according to claim 5, characterized in that, The bottom of the sliding plate (203) is provided with a sloping groove (204), the end of the extrusion rod (202) is fitted with the inside of the sloping groove (204), a return spring (206) is fixed at the protruding end of the heat dissipation fin (205), the end of the return spring (206) is fixed at the protruding part of the outer wall of the sliding plate (203), and an air inlet (207) is provided at the bottom of the outer shell. The air inlet (207) is used to remove the heat from the heat dissipation fin (205).

7. A real-time network data monitoring device based on a next-generation information network according to claim 6, characterized in that, The limiting device includes: an elastic sheet (301), the end of which is fixed to the outer wall of the fixing cover (6); A fixing block (302) is fixed to the inside of the sliding frame (201); Guide block (303) is fixed to the outer wall of the fixed cover (6), and a limit hole (307) is provided on the top of the guide block (303).

8. A real-time network data monitoring device based on a next-generation information network according to claim 7, characterized in that, A limiting rod (304) passes through the fixing block (302) and fits snugly at the penetration point. The cooperation between the limiting rod (304) and the limiting hole (307) is used to fix the heat dissipation fins (205). A handle (306) is fixed to the top of the limiting rod (304), and a return spring (305) is fixed to the bottom of the handle (306). The bottom of the return spring (305) is fixed to the top of the fixing block (302).