A network security cabinet

By combining the design of air deflectors, fan assemblies, and heat pipe components with adjustable brackets and protective components, the heat dissipation and equipment fixation problems of network security cabinets are solved, achieving efficient heat dissipation, flexible deployment, and security protection, adapting to the needs of various application scenarios.

CN224343609UActive Publication Date: 2026-06-09JIN JIAN COMMERCIAL FACTORING (HENGQIN) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIN JIAN COMMERCIAL FACTORING (HENGQIN) CO LTD
Filing Date
2025-06-06
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Existing network security cabinets have limitations in heat dissipation methods, relying on complex liquid circulation or external cold sources, and the equipment fixing methods are inflexible, making them unable to adapt to various scenario requirements.

Method used

The system employs a combination of air deflectors, fan assemblies, and heat pipe components for efficient heat dissipation. Combined with adjustable brackets and protective components, it enables flexible installation and angle adjustment of the equipment, enhancing the stability and security of the cabinet.

Benefits of technology

It achieves efficient heat dissipation, improves the space utilization and applicability of the equipment, reduces installation and maintenance costs, enhances the shock resistance and sealing performance of the cabinet, and meets the needs of various application scenarios.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The utility model relates to the technical field of network security equipment, especially network security cabinet, it includes cabinet main body, heat dissipation module, adjustment support and protection component. Heat dissipation module realizes high -efficient cooling through deflector, fan group and heat pipe component, and adjustment support utilizes slide rail and positioning block and adjusts equipment position and angle flexibly, and protection component passes through top cover, base and buffer unit and promotes the shock resistance and security. The utility model discloses the combination design through deflector, fan group and heat pipe component, utilizes the air flow along the predetermined path flow of guide groove and is combined with the forced air supply of fan group and the high -efficient heat conduction capacity of heat pipe component, can reduce the temperature inside the cabinet quickly, avoids the equipment performance decline or damage due to high temperature. Meanwhile, the heat absorption end of heat pipe component is close to the heating part, and the heat dissipation end extends to the external environment, ensures that heat can be quickly conducted to the outside, solves the problem that traditional cooling system relies on complex liquid circulation or external cold source.
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Description

Technical Field

[0001] This utility model belongs to the field of network security equipment technology, specifically a network security cabinet. Background Technology

[0002] Network security cabinets are mainly used to house critical facilities such as servers and network equipment, providing a stable and secure operating environment for modern data centers, enabling the equipment to work normally under efficient heat dissipation conditions and a reasonable spatial layout.

[0003] Currently, network security cabinets still have significant limitations in terms of heat dissipation methods. They generally rely on complex liquid circulation or external cold sources for cooling. However, such complex and expensive cooling systems or their high dependence on the external environment limit their application scope. At the same time, the screw fixing method commonly used for the internal equipment of current network security cabinets does not allow for flexible adjustment of the installation position and angle of the equipment. The spatial layout is relatively simple and cannot adapt to the needs of various scenarios. Therefore, current network security cabinets lack a solution that can adapt to the needs of various scenarios and achieve both efficient heat dissipation and flexible deployment. Utility Model Content

[0004] The purpose of this utility model is to provide a network security cabinet to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution:

[0006] A network security cabinet includes a cabinet body, a heat dissipation module, an adjustment bracket, and protective components. The heat dissipation module is embedded in the side wall of the cabinet body for efficient cooling of internal equipment. The adjustment bracket is fixedly installed on the inner wall of the cabinet body for flexible adjustment of the installation position and angle of the equipment. The protective components are located at the top and bottom of the cabinet body to improve the security and stability of the cabinet.

[0007] Furthermore, the bottom of the cabinet body is fixedly connected to a support frame by bolts. The bottom of the support frame is equipped with an anti-slip pad, which is fastened to the support frame with screws to enhance the stability of the cabinet when placed. The top of the cabinet body has multiple ventilation holes, each covered with a filter screen. The filter screen is detachably connected to the cabinet body via a snap-fit ​​structure to prevent external dust from entering the cabinet.

[0008] Furthermore, the heat dissipation module includes a guide plate, a fan assembly, and a heat pipe assembly. The guide plate is fixedly installed on the inner side wall of the main body of the rack. The surface of the guide plate has multiple guide grooves evenly distributed, and the cross-section of the guide grooves is arc-shaped to guide airflow along a predetermined path. The fan assembly is fixedly installed on one side of the guide plate by bolts, and the air outlet of the fan assembly faces the interior of the main body of the rack. The heat pipe assembly is fixedly installed on the back plate of the main body of the rack by clamps. The heat absorption end of the heat pipe assembly is close to the heat-generating part of the server equipment, and the heat dissipation end of the heat pipe assembly extends to the exterior of the main body of the rack to quickly conduct heat to the external environment.

[0009] Furthermore, the adjusting bracket includes a fixed frame, a slide rail, and a positioning block. The fixed frame is fixedly installed on the inner wall of the cabinet body by bolts. The slide rail is welded to the inner side of the fixed frame. The surface of the slide rail is provided with a rack. The positioning block is connected to the slide rail by a gear. The outer side of the positioning block is provided with a locking knob for fixing the positioning block at any position on the slide rail. The front end of the positioning block is provided with an equipment tray. The equipment tray is connected to the positioning block by a hinge for adjusting the tilt angle of the equipment according to actual needs.

[0010] Furthermore, the protective assembly includes a top cover, a base, and a buffer unit. The top cover is bolted to the top of the cabinet body, and an insulation layer is provided on the inner side of the top cover. The insulation layer is fixedly connected to the top cover with adhesive to reduce the impact of external heat on the cabinet interior. The base is bolted to the bottom of the cabinet body, and a shock-absorbing cavity is provided inside the base. The shock-absorbing cavity is filled with elastic material to absorb external impact forces. The buffer unit includes a spring and a guide rod. The spring is sleeved on the outside of the guide rod, and the two ends of the guide rod are fixedly connected to the cabinet body and the base, respectively, to further improve the cabinet's shock resistance.

[0011] Furthermore, the front side of the main body of the cabinet is provided with a double door structure, which is hinged to the main body of the cabinet via hinges. The inner side of the double door structure is provided with a sealing strip, which is fixedly connected to the double door structure with adhesive to enhance the airtightness of the cabinet. The outer side of the double door structure is provided with a handle, which is fixedly connected to the double door structure with screws to facilitate opening and closing of the cabinet.

[0012] Compared with the prior art, the technical effects of this utility model are:

[0013] This invention utilizes a combination design of a baffle plate, a fan assembly, and a heat pipe component. By guiding airflow along a predetermined path using a baffle channel, and combining the forced airflow of the fan assembly with the efficient heat conduction of the heat pipe component, it can rapidly reduce the internal temperature of the server rack, preventing performance degradation or damage to equipment due to high temperatures. Simultaneously, the heat-absorbing end of the heat pipe component is close to the heat-generating part, while the heat-dissipating end extends to the external environment, ensuring rapid heat transfer to the outside. This solves the problem of traditional cooling systems relying on complex liquid circulation or external cold sources, reducing installation and maintenance costs and improving heat dissipation efficiency.

[0014] This invention, through the design of an adjustable bracket, utilizes the cooperation of slide rails and positioning blocks to flexibly adjust the installation position and angle of the equipment, meeting the installation needs of equipment of different sizes or types, and improving the space utilization and applicability of the cabinet. The equipment tray is connected to the positioning block via hinges, allowing the tilt angle of the equipment to be adjusted according to actual needs, facilitating maintenance and repair by operators, and enhancing the flexibility and practicality of the cabinet.

[0015] This utility model utilizes a combination design of a top cover, base, and buffer unit. An insulation layer reduces the impact of external heat on the cabinet's interior. Combined with the dual protection of the shock-absorbing cavity and buffer unit, it effectively absorbs external impact forces, improving the cabinet's shock resistance and ensuring stable operation of equipment in harsh environments. The double-door structure's sealing strip design enhances the cabinet's airtightness, preventing external dust and moisture from entering, further improving the cabinet's safety and reliability.

[0016] In summary, this utility model, through the synergistic effect of the heat dissipation module, the adjustable bracket, and the protective components, solves the shortcomings of existing network security cabinets in terms of heat dissipation methods, spatial layout, and security protection. It provides a solution that can adapt to various application scenarios and take into account both efficient heat dissipation and flexible deployment, thus meeting the higher requirements of modern data centers for a stable operating environment. Attached Figure Description

[0017] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0018] Figure 1 This is a schematic diagram of the overall structure of the network security cabinet according to an embodiment of the present utility model;

[0019] Figure 2 This is a schematic diagram of the heat dissipation module structure according to an embodiment of the present utility model.

[0020] Figure 3 This is a schematic diagram of the adjustment bracket structure according to an embodiment of the present utility model.

[0021] Figure 4 This is a schematic diagram of the protective component structure and the double-door structure according to the embodiments of this utility model.

[0022] In the picture:

[0023] 1. Cabinet body; 2. Heat dissipation module; 3. Adjustable bracket; 4. Protective components; 5. Support legs; 6. Anti-slip pads; 7. Ventilation holes; 8. Filter screen; 9. Air guide plate; 10. Fan assembly; 11. Heat pipe assembly; 12. Fixing frame; 13. Slide rail; 14. Positioning block; 15. Equipment tray; 16. Top cover; 17. Base; 18. Buffer unit; 19. Double door structure; 20. Sealing strip; 21. Handle. Detailed Implementation

[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0025] This utility model provides a network security cabinet, the structure and function of which rely on the rational layout of multiple components and their interconnections and cooperation. The specific embodiments of this utility model are described in detail below with reference to the accompanying drawings. Figure 1 This is a schematic diagram of the overall structure of the present invention, showing the layout of the main cabinet 1, heat dissipation module 2, adjustment bracket 3 and protective components 4. Figures 2 to 4 The specific structure of the heat dissipation module 2, the adjustment bracket 3, the protective component 4, and the double door structure 19, as well as the connection relationship between the components, are shown respectively.

[0026] like Figure 1As shown, the main cabinet 1 serves as the frame structure of the entire device. Its bottom is bolted to support legs 5, and the bottom of the support legs 5 is equipped with anti-slip pads 6, which are securely connected to the support legs 5 with screws. The design of the support legs 5 ensures the stability of the main cabinet 1 on the ground or other mounting surfaces, while the anti-slip pads 6 further enhance the anti-slip capability of the main cabinet 1 during use. Multiple ventilation holes 7 are provided at the top of the main cabinet 1, each covered with a filter screen 8. The filter screen 8 is detachably connected to the main cabinet 1 via a snap-fit ​​structure. This design allows outside air to enter the cabinet through the ventilation holes 7, while the filter screen 8 effectively prevents dust from entering the main cabinet 1, thus keeping the internal equipment clean.

[0027] The heat dissipation module 2 is embedded in the side wall of the main body 1 of the cabinet, and its specific structure is as follows: Figure 2 As shown. The heat dissipation module 2 includes a guide plate 9, a fan assembly 10, and a heat pipe assembly 11. The guide plate 9 is fixedly installed on the inner side wall of the rack body 1, and its surface has multiple evenly distributed guide grooves with an arc-shaped cross-section. The fan assembly 10 is fixedly installed on one side of the guide plate 9 by bolts, with the air outlet of the fan assembly 10 facing the interior of the rack body 1. The heat pipe assembly 11 is fixedly installed on the back plate of the rack body 1 by clamps, with the heat absorption end of the heat pipe assembly 11 close to the heat-generating part of the server equipment, and the heat dissipation end extending to the exterior of the rack body 1. The guide grooves on the guide plate 9 are used to guide the airflow along a predetermined path, the fan assembly 10 forces the airflow into the interior of the rack body 1, and the heat pipe assembly 11 quickly conducts the heat generated by the server equipment to the external environment. This design ensures that the temperature inside the rack body 1 can be effectively controlled.

[0028] The adjustment bracket 3 is fixedly installed on the inner wall of the main body 1 of the cabinet, and its specific structure is as follows: Figure 3 As shown. The adjusting bracket 3 includes a fixed frame 12, a slide rail 13, and a positioning block 14. The fixed frame 12 is fixedly installed on the inner wall of the cabinet body 1 by bolts. The slide rail 13 is welded to the inner side of the fixed frame 12, and the surface of the slide rail 13 is provided with a rack. The positioning block 14 is connected to the slide rail 13 by gear meshing. The outer side of the positioning block 14 is provided with a locking knob for fixing the positioning block 14 at any position on the slide rail 13. The front end of the positioning block 14 is provided with an equipment tray 15, which is connected to the positioning block 14 by a hinge. Of course, it can also be integrally formed or connected by a locking nut. This utility model does not limit this, as long as the design of the equipment tray 15 allows the operator to adjust the tilt angle of the equipment according to actual needs, and the cooperation between the positioning block 14 and the slide rail 13 enables flexible adjustment of the equipment installation position. This design allows the cabinet body 1 to adapt to the installation needs of equipment of different sizes or types.

[0029] Protective components 4 are located at the top and bottom of the main body 1 of the cabinet, and their specific structure is as follows: Figure 4 As shown. The protective component 4 includes a top cover 16, a base 17, and a buffer unit 18. The top cover 16 is bolted to the top of the cabinet body 1, and the inner side of the top cover 16 has a heat insulation layer, which is fixedly connected to the top cover 16 with adhesive. The base 17 is bolted to the bottom of the cabinet body 1, and the base 17 has a shock-absorbing cavity filled with elastic material. The buffer unit 18 includes a spring and a guide rod. The spring is sleeved on the outside of the guide rod, and the two ends of the guide rod are fixedly connected to the cabinet body 1 and the base 17, respectively. The heat insulation layer of the top cover 16 reduces the impact of external heat on the interior of the cabinet body 1, while the shock-absorbing cavity of the base 17 and the buffer unit 18 work together to absorb external impact forces, improving the shock resistance of the cabinet body 1.

[0030] The double-door structure 19 is located on the front side of the main body of the rack 1, and its specific structure is as follows: Figure 4 As shown. The double-door structure 19 is hinged to the cabinet body 1 via hinges. A sealing strip 20 is provided on the inner side of the double-door structure 19, and the sealing strip 20 is fixedly connected to the double-door structure 19 with adhesive. A handle 21 is provided on the outer side of the double-door structure 19, and the handle 21 is fixedly connected to the double-door structure 19 with screws. The design of the sealing strip 20 enhances the airtightness of the cabinet body 1, preventing external dust and moisture from entering the cabinet body 1, while the handle 21 facilitates the opening and closing of the double-door structure 19 by the operator.

[0031] The operating principle of this invention is as follows: When the server equipment inside the main cabinet 1 is running, it generates a large amount of heat. At this time, the fan assembly 10 in the heat dissipation module 2 starts, forcibly introducing external air into the main cabinet 1. The guide grooves on the guide plate 9 guide the airflow along a predetermined path, allowing the airflow to evenly cover the surface of the server equipment. The heat absorption end of the heat pipe assembly 11 is close to the heat-generating part of the server equipment, quickly transferring heat to the heat dissipation end, and releasing the heat to the external environment through the heat dissipation end. This heat dissipation method avoids the dependence of traditional cooling systems on complex liquid circulation or external cold sources, reduces installation and maintenance costs, and improves heat dissipation efficiency.

[0032] The adjustable bracket 3 allows operators to adjust the installation position and angle of the equipment according to actual needs. The positioning block 14 is connected to the slide rail 13 via gears, and operators can fix the positioning block 14 to any position on the slide rail 13 by rotating the locking knob. The equipment tray 15 is connected to the positioning block 14 via hinges, allowing operators to adjust the tilt angle of the equipment tray 15 as needed for maintenance and repair. This design improves the space utilization and applicability of the cabinet body 1.

[0033] The design of protective component 4 further enhances the safety and stability of the rack body 1. The heat insulation layer of the top cover 16 reduces the impact of external heat on the interior of the rack body 1, while the shock-absorbing cavity and buffer unit 18 of the base 17 work together to absorb external impact forces. This design enables the rack body 1 to maintain stable operation in harsh environments. The sealing strip 20 of the double-door structure 19 enhances the airtightness of the rack body 1, preventing external dust and moisture from entering the interior of the rack body 1, further improving the safety and reliability of the rack body 1.

[0034] This utility model, through the synergistic effect of the heat dissipation module 2, the adjustment bracket 3, and the protective component 4, solves the shortcomings of existing network security cabinets in terms of heat dissipation methods, spatial layout, and security protection, and provides a solution that can adapt to various application scenarios while taking into account both efficient heat dissipation and flexible deployment.

[0035] To enable those skilled in the art to fully understand and implement this utility model, the following detailed explanation of its operating principle and implementation steps is provided in conjunction with specific application scenarios.

[0036] In practical applications, the main cabinet 1 is installed in the core area of ​​a data center to house multiple server devices. The support legs 5 are bolted to the ground, and anti-slip pads 6 enhance stability, ensuring that the entire cabinet 1 will not slip or tip over under high load. The ventilation holes 7 allow outside air to flow smoothly into the cabinet, while the filter 8 effectively blocks dust and impurities, ensuring the cleanliness of the cabinet interior and extending the lifespan of the equipment.

[0037] When the server equipment starts operating, it generates a large amount of heat. At this time, the heat dissipation module 2 initiates its workflow. The fan assembly 10 first introduces external cool air into the cabinet body 1 through forced airflow. The arc-shaped guide grooves on the air guide plate 9 guide the airflow along a predetermined path, ensuring it evenly covers the surface of the server equipment. The heat absorption end of the heat pipe assembly 11 is close to the heat-generating parts of the server equipment, rapidly absorbing heat and transferring it to the heat dissipation end through thermal conduction. The heat dissipation end extends to the outside of the cabinet body 1, releasing the heat into the environment, thereby achieving efficient cooling. This design avoids the dependence of traditional cooling systems on complex liquid circulation or external cold sources, significantly reducing installation and maintenance costs while improving heat dissipation efficiency.

[0038] In the application of the adjustable bracket 3, the operator adjusts the installation position of the server equipment according to its size and type. First, the positioning block 14 is engaged with the slide rail 13 via gears. The operator rotates the locking knob to loosen the positioning block 14, moves it along the slide rail 13 to the appropriate position, and then re-locks it. The equipment tray 15 is connected to the positioning block 14 via hinges, allowing the operator to adjust the tilt angle of the equipment tray 15 as needed for installation, maintenance, and repair. This flexible adjustment design not only improves the space utilization of the main cabinet 1 but also enhances its ability to adapt to different equipment needs.

[0039] Protective component 4 plays a crucial role in harsh environments. The heat insulation layer inside the top cover 16 reduces the impact of external heat on the interior of the cabinet body 1, effectively maintaining the stability of the internal temperature, especially in high-temperature environments. The shock-absorbing cavity and buffer unit 18 inside the base 17 work together to absorb external impact forces. When the cabinet body 1 is subjected to vibration or impact, the buffer unit 18, composed of springs and guide rods, absorbs energy through elastic deformation, thereby protecting the internal equipment from damage. The sealing strip 20 of the double-door structure 19 further enhances the airtightness of the cabinet body 1, preventing external dust and moisture from entering the cabinet and ensuring the safety and reliability of the equipment.

[0040] In actual operation, the double-door structure 19 provides convenience for operators. After opening the double-door structure 19 via the handle 21, operators can quickly access the server equipment inside the rack. The sealing strip 20 ensures that the rack maintains good sealing performance even with frequent door opening and closing, preventing external environmental factors from affecting the internal equipment.

[0041] In summary, the network security cabinet of this invention achieves efficient heat dissipation, flexible deployment, and secure protection in practical application scenarios through the synergistic effect of the heat dissipation module 2, the adjustable bracket 3, and the protective components 4. This design not only solves the problems existing in the prior art but also meets the higher requirements of modern data centers for a stable operating environment, and has broad application prospects.

[0042] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A network security cabinet, comprising a cabinet body (1), a heat dissipation module (2), an adjustment bracket (3), and protective components (4), characterized in that, The heat dissipation module (2) is embedded in the side wall of the cabinet body (1). The adjustment bracket (3) is fixedly installed on the inner wall of the cabinet body (1). The protective component (4) is set at the top and bottom of the cabinet body (1). The bottom end of the cabinet body (1) is fixedly connected to the support leg (5) by bolts. The bottom of the support leg (5) is provided with an anti-slip pad (6). The anti-slip pad (6) is fastened to the support leg (5) by screws. The top of the cabinet body (1) is provided with multiple ventilation holes (7). Each ventilation hole (7) is covered with a filter screen (8). The filter screen (8) is detachably connected to the cabinet body (1) by a snap-fit ​​structure.

2. A network security cabinet according to claim 1, characterized in that, The heat dissipation module (2) includes a guide plate (9), a fan assembly (10), and a heat pipe assembly (11). The guide plate (9) is fixedly installed on the inner side wall of the main body of the cabinet (1). The surface of the guide plate (9) is evenly distributed with multiple guide grooves with arc-shaped cross sections. The fan assembly (10) is fixedly installed on one side of the guide plate (9) by bolts. The air outlet of the fan assembly (10) faces the inside of the main body of the cabinet (1). The heat pipe assembly (11) is fixedly installed on the back plate of the main body of the cabinet (1) by clamps. The heat absorption end of the heat pipe assembly (11) is close to the heat-generating part of the server equipment, and the heat dissipation end of the heat pipe assembly (11) extends to the outside of the main body of the cabinet (1).

3. A network security cabinet according to claim 1, characterized in that, The adjustment bracket (3) includes a fixed frame (12), a slide rail (13) and a positioning block (14). The fixed frame (12) is fixedly installed on the inner wall of the cabinet body (1) by bolts. The slide rail (13) is welded to the inner side of the fixed frame (12). The surface of the slide rail (13) is provided with a rack. The positioning block (14) is connected to the slide rail (13) by gear meshing. The outer side of the positioning block (14) is provided with a locking knob. The front end of the positioning block (14) is provided with an equipment tray (15). The equipment tray (15) is connected to the positioning block (14) by a hinge.

4. A network security cabinet according to claim 1, characterized in that, The protective component (4) includes a top cover (16), a base (17), and a buffer unit (18). The top cover (16) is fixedly installed on the top of the cabinet body (1) by bolts. The inner side of the top cover (16) is provided with a heat insulation layer. The heat insulation layer is fixedly connected to the top cover (16) by adhesive. The base (17) is fixedly installed on the bottom of the cabinet body (1) by bolts. The base (17) is provided with a shock-absorbing cavity inside. The shock-absorbing cavity is filled with elastic material. The buffer unit (18) includes a spring and a guide rod. The spring is sleeved on the outside of the guide rod. The two ends of the guide rod are fixedly connected to the cabinet body (1) and the base (17) respectively.

5. A network security cabinet according to claim 1, characterized in that, The front side of the cabinet body (1) is provided with a double door structure (19). The double door structure (19) is hinged to the cabinet body (1) by a hinge. The inner side of the double door structure (19) is provided with a sealing strip (20). The sealing strip (20) is fixedly connected to the double door structure (19) by an adhesive. The outer side of the double door structure (19) is provided with a handle (21). The handle (21) is fixedly connected to the double door structure (19) by a screw.