A data acquisition server

By introducing heat dissipation components and cabling structures into the data acquisition server, the heat dissipation performance and line management were optimized, solving the problems of insufficient server heat dissipation and messy wiring, and achieving efficient and stable operation and convenient maintenance.

CN224457331UActive Publication Date: 2026-07-03Jiangxi Vocational and Technical University

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
Jiangxi Vocational and Technical University
Filing Date
2025-06-23
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing data acquisition servers have shortcomings in terms of heat dissipation efficiency and structural stability. In particular, small servers are prone to heat buildup in high-temperature environments, which can affect equipment performance and lifespan. Furthermore, messy wiring can lead to operational problems.

Method used

The heat dissipation components used on the outside of the server frame include an outer edge heat dissipation mesh, vertical and side heat dissipation fans, a top cover and cable assemblies. The heat dissipation performance is optimized through directional airflow and gas circulation, and the cable is organized through a ladder frame and fixing bolts to ensure stability and convenient maintenance.

Benefits of technology

It improves the server's heat dissipation efficiency and structural stability, ensuring stable operation in high-temperature environments, and the wiring is neat and orderly, facilitating maintenance and replacement.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model provides a data acquisition server, relating to the field of electronic equipment technology. It includes a server frame with a server heat dissipation assembly on its outer side. The outer side of the server frame is equipped with an outer edge heat dissipation mesh. A data acquisition server is installed on the inner side of the server frame. Heat dissipation fins are welded to the left and right sides of the data acquisition server. Vertical cooling fans are installed on the outer sides of the heat dissipation fins, and a side cooling fan is located in front of each vertical cooling fan. The side cooling fans draw air from side air vents, forming a directional airflow that is directed towards the outer edge heat dissipation mesh, accelerating air circulation and effectively cooling the heat dissipation fins, achieving directional and precise heat dissipation. The vertical cooling fans, by increasing their size and airflow area, enhance the airflow speed within the server frame, improving the overall heat dissipation effect. Combined with the large area of ​​the cover, this optimizes the overall heat dissipation performance.
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Description

Technical Field

[0001] This utility model relates to the field of electronic equipment technology, and in particular to a data acquisition server. Background Technology

[0002] A data acquisition server is a dedicated server used to centrally collect, process, and store data transmitted from various front-end devices (such as sensors, instruments, etc.). It acquires scattered data in real time through network interfaces, filters, transforms, and integrates it, providing unified and reliable data support for data analysis, monitoring systems, or business applications, and ensuring the efficiency and stability of data acquisition.

[0003] A search revealed that the announcement number "CN222582790U" mentions "this utility model discloses an intelligent data acquisition server, including: a server cabinet and a fan fixedly connected to the right side of the server cabinet; the server cabinet is provided with a clamping mechanism, which includes a sliding groove, a sliding plate, and a threaded rod, the sliding groove being opened inside the lower side of the server cabinet; a dehumidification structure is provided on the upper inner side of the server cabinet, the dehumidification structure including a cooling mechanism, a serpentine tube, and a water collection tank, the cooling mechanism being fixedly installed on the upper side of the server cabinet." In use, this intelligent data acquisition server uses the fixing plate and threaded rod to clamp the server box, reducing the shaking of the electronic components inside the server box. The serpentine tube accelerates the condensation of hot air, which then collects in the water collection tank, preventing dripping onto the server box and affecting its lifespan. The filter is easy to replace, minimizing the entry of dust and other impurities into the server cabinet.

[0004] However, during the use of servers, especially small servers, the heat dissipation efficiency and structural stability are crucial, particularly air cooling. However, due to server operation issues, a large amount of heat is generated. If this heat cannot be dissipated in time, it will cause the internal temperature of the server to rise, affecting the performance and lifespan of the equipment. Furthermore, if the internal wiring of the server is messy, it can also easily cause obstacles to the internal operation of the server.

[0005] Therefore, we provide a data acquisition server to solve the above problems. Utility Model Content

[0006] To overcome the above deficiencies, this utility model provides a data acquisition server, which aims to solve the problems mentioned above.

[0007] To achieve the above objectives, this utility model provides the following technical solution:

[0008] A data acquisition server includes a server frame, a server heat dissipation assembly on the outer side of the server frame, an outer edge heat dissipation mesh on both sides of the server frame, a data acquisition server mounted on the inner side of the server frame, heat dissipation fins welded to the left and right sides of the data acquisition server, a vertical cooling fan mounted on the outer side of each heat dissipation fin, a side cooling fan mounted in front of each vertical cooling fan, a cover edge welded to the upper side of the server frame, an upper cover mounted on the inner side of the cover edge, a server expansion panel connected to the front of the server frame via a slot, a limit slot provided at the inner end of the front side of the cover edge, side air vents on both the left and right sides of the server expansion panel, and a cable assembly mounted on the inner wall of the cover edge.

[0009] As a further description of the above technical solution:

[0010] The outer heat dissipation mesh is welded to the server frame. The outer heat dissipation mesh is located at the left and right ends and the rear of the server frame. The outer heat dissipation mesh is a porous steel mesh structure.

[0011] As a further description of the above technical solution:

[0012] The side cooling fan is connected to the inner side of the server expansion panel by screws. The side cooling fan and the outer edge heat dissipation mesh form an air guide structure. The side cooling fan and the side air guide are correspondingly arranged.

[0013] As a further description of the above technical solution:

[0014] The vertical cooling fans are arranged in two groups on the left and right sides of the data acquisition server, with each group consisting of two fans. The vertical cooling fans guide the airflow through the upper cover.

[0015] As a further description of the above technical solution:

[0016] The upper end of the server expansion panel is connected to the limiting slot by a slot, and the lower end of the server expansion panel is connected to the server frame by bolts.

[0017] As a further description of the above technical solution:

[0018] The inner wall of the cover edge is provided with bolt holes, and a trapezoidal frame is provided on the outside of the bolt holes. A fixing bolt passes through the trapezoidal frame and the bolt hole. The trapezoidal frames are arranged symmetrically in two groups on the left and right.

[0019] Compared with the prior art, the beneficial effects of this utility model are:

[0020] By configuring server cooling components, side-mounted cooling fans draw air from side air vents to create directional airflow, which is then directed outward along the cooling mesh to accelerate air circulation and effectively cool the heat dissipation fins, achieving a directional and precise heat dissipation effect. Meanwhile, vertical cooling fans, by increasing their size and airflow area, enhance the airflow speed within the server frame, improving the overall heat dissipation effect. Combined with the large area of ​​the cover, this optimizes the overall heat dissipation performance.

[0021] By setting up the server expansion panel and cable assembly, the upper end of the server expansion panel is inserted into the limiting slot, and the lower end is fixed to the server frame with bolts to ensure the panel is stable and makes it easier to replace and repair in the future. The cables are also inserted into the grooves of the trapezoidal bracket, and the trapezoidal bracket is inserted into the bolt holes through the fixing bolts to achieve the function of organizing the cables and avoiding cable mess. Attached Figure Description

[0022] 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.

[0023] Figure 1 This is a schematic diagram of the overall appearance structure of this utility model;

[0024] Figure 2 This is a schematic diagram of the overall bottom view of the present invention;

[0025] Figure 3 This is a schematic diagram of the overall front inner structure of this utility model;

[0026] Figure 4 This is a schematic diagram of the overall back inner structure of this utility model;

[0027] Figure 5 This is a schematic diagram of the disassembled structure of the ribbon cable assembly of this utility model.

[0028] The diagram is labeled as follows: 1. Server frame; 2. Server heat dissipation assembly; 201. Outer edge heat dissipation mesh; 202. Data acquisition server; 203. Heat dissipation fins; 204. Vertical cooling fan; 205. Side cooling fan; 206. Cover edge; 207. Top cover; 208. Server expansion panel; 209. Limiting slot; 210. Side air vent; 3. Cable assembly; 301. Bolt hole; 302. Trapezoidal frame; 303. Fixing bolt. Detailed Implementation

[0029] 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.

[0030] Please see Figure 1-5 As shown, this utility model provides a technical solution: a data acquisition server, including a server frame 1, a server heat dissipation component 2 is provided on the outer side of the server frame 1, an outer edge heat dissipation mesh 201 is provided on the outer side of the server frame 1, a data acquisition server 202 is installed on the inner side of the server frame 1, heat dissipation fins 203 are welded on the left and right sides of the data acquisition server 202, a vertical heat dissipation fan 204 is installed on the outer side of the heat dissipation fins 203, a side heat dissipation fan 205 is provided on the front side of the vertical heat dissipation fan 204, a cover edge 206 is welded on the upper side of the server frame 1, an upper cover 207 is installed on the inner side of the cover edge 206, a server expansion panel 208 is connected to the front side of the server frame 1 by a slot, a limit slot 209 is provided on the inner end of the front side of the cover edge 206, side air vents 210 are provided on the left and right sides of the server expansion panel 208, and a cable assembly 3 is provided on the inner wall of the cover edge 206.

[0031] Continue reading Figure 1-5 As shown, each inner wall of the cover edge 206 is provided with a bolt hole 301, and a trapezoidal frame 302 is provided on the outer side of the bolt hole 301. A fixing bolt 303 passes through the trapezoidal frame 302 and the bolt hole 301. The trapezoidal frames 302 are arranged symmetrically in two groups on the left and right. When needed, the wire is inserted into the groove of the trapezoidal frame 302, and then the trapezoidal frame 302 is inserted into the bolt hole 301 through the fixing bolt 303 to achieve the function of tidying up the wire and avoiding the wire from becoming messy.

[0032] Continue reading Figure 1-5 As shown, the outer heat dissipation mesh 201 is welded to the server frame 1. The outer heat dissipation mesh 201 is located at the left and right ends and the rear of the server frame 1. The outer heat dissipation mesh 201 is a steel porous mesh structure. When needed, the three-way ventilation of the outer heat dissipation mesh 201 can effectively improve heat dissipation efficiency and performance, ensuring smooth ventilation and stable operation of the data acquisition server 202 in high-temperature environments.

[0033] Continue reading Figure 1-5As shown, the upper end of the server expansion panel 208 is connected to the limiting slot 209 by a slot, and the lower end of the server expansion panel 208 is connected to the server frame 1 by a bolt. When needed, the upper end of the server expansion panel 208 is inserted into the limiting slot 209, and the lower end is fixed to the server frame 1 with bolts to ensure the panel is stable and to make subsequent replacement and maintenance more convenient.

[0034] Continue reading Figure 1-5 As shown, the vertical cooling fans 204 are arranged in two groups on the left and right sides of the data acquisition server 202. Each group of vertical cooling fans 204 is set in pairs. The vertical cooling fans 204 guide the airflow through the upper cover 207. When needed, the vertical cooling fans 204 increase their volume and airflow area to enhance the airflow speed within the server frame 1, thereby improving the overall heat dissipation effect. In addition, the large area of ​​the upper cover 207 further optimizes the overall heat dissipation performance.

[0035] Continue reading Figure 1-5 As shown, the side cooling fan 205 is connected to the inner side of the server expansion panel 208 by screws. The side cooling fan 205 and the outer edge heat dissipation mesh 201 form an air guiding structure. The side cooling fan 205 and the side air guide 210 are correspondingly arranged. When needed, the side cooling fan 205 draws air from the side air guide 210 to form a directional airflow, which is guided to the outer edge heat dissipation mesh 201 to accelerate air circulation and effectively cool the heat dissipation fins 203, achieving the effect of directional and precise heat dissipation.

[0036] Working principle: When needed, the data acquisition server 202 is installed into the server frame 1. Then, the upper end of the server expansion panel 208 is inserted into the limiting slot 209. After preparation, the vertical cooling fan 204 and the side cooling fan 205 are installed on the inner bottom of the server frame 1 and the back of the side air vent 210, respectively, to form a convection airflow. Then, the cable is inserted into the trapezoidal frame 302, and the trapezoidal frame 302 is secured into the bolt hole 301 by the fixing bolt 303. Then, the upper cover 207 is fixedly installed along the cover edge 206. After preparation, the data acquisition server 202 is started. The vertical cooling fan 204 exhausts air through the upper cover 207, while the side cooling fan 205 guides air into the server frame 1 through the side air vent 210, blowing air onto the heat dissipation fins 203 for air cooling. The hot air is exhausted through the outer edge heat dissipation mesh 201. This completes the use of a data acquisition server.

[0037] Although embodiments of the present 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 present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A data collection server comprising a server framework (1), characterized in that: A server heat dissipation assembly (2) is provided on the outside of the server frame (1). An outer edge heat dissipation mesh (201) is provided on the outside of the server frame (1). A data acquisition server (202) is installed on the inside of the server frame (1). Heat dissipation fins (203) are welded on the left and right sides of the data acquisition server (202). A vertical cooling fan (204) is installed on the outside of the heat dissipation fins (203). A side cooling fan is provided on the front side of the vertical cooling fan (204). (205) A cover edge (206) is welded to the upper side of the server frame (1). An upper cover (207) is installed on the inner side of the cover edge (206). A server expansion panel (208) is connected to the front slot of the server frame (1). A limit slot (209) is provided at the inner end of the front side of the cover edge (206). Side air vents (210) are provided on both the left and right sides of the server expansion panel (208). Cable assembly (3) is provided on the inner wall of the cover edge (206).

2. The data collection server of claim 1, wherein, The outer heat dissipation mesh (201) is welded to the server frame (1). The outer heat dissipation mesh (201) is located at the left and right ends and the rear side of the server frame (1). The outer heat dissipation mesh (201) is a steel porous mesh structure.

3. The data collection server of claim 1, wherein, The side cooling fan (205) is connected to the inner side of the server expansion panel (208) by screws. The side cooling fan (205) and the outer edge heat dissipation mesh (201) form an air guide structure. The side cooling fan (205) and the side air guide (210) are correspondingly arranged.

4. The data collection server of claim 1, wherein, The vertical cooling fans (204) are arranged in two groups on the left and right sides of the data acquisition server (202). The vertical cooling fans (204) are arranged in pairs in each group. The vertical cooling fans (204) guide the air flow through the upper cover (207).

5. The data collection server of claim 1, wherein, The upper end of the server expansion panel (208) is connected to the limiting slot (209) by a slot, and the lower end of the server expansion panel (208) is connected to the server frame (1) by bolts.

6. The data collection server of claim 1, wherein, The inner wall of the cover edge (206) is provided with bolt holes (301), and a trapezoidal frame (302) is provided on the outside of the bolt holes (301). A fixing bolt (303) passes through the trapezoidal frame (302) and the bolt holes (301). The trapezoidal frames (302) are arranged in two symmetrical groups on the left and right.