A high-efficiency machine room

By designing a rotating shaft and fixing rod structure in the machine room, automatic cleaning and convenient installation of the filter plates are achieved, solving the problem of low filter plate cleaning efficiency and ensuring the efficient operation of the ventilation system and the stability of the equipment.

CN224401910UActive Publication Date: 2026-06-23CHONGQING XIANGQIAN MECHANICAL & ELECTRICAL EQUIPMENT ENGINEERING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHONGQING XIANGQIAN MECHANICAL & ELECTRICAL EQUIPMENT ENGINEERING CO LTD
Filing Date
2025-06-09
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

The existing filter plate cleaning efficiency in the computer room is not high, which affects the ventilation operation.

Method used

Design an efficient machine room that adopts a rotating shaft and fixed rod structure. The rotating shaft is driven by a motor to drive the scraper to rotate synchronously, so as to clean the dust on both sides of the filter plate at the same time. The filter plate can be easily installed and removed through a limit mechanism, and the machine room equipment is cooled by a cooling mechanism.

Benefits of technology

It improves the efficiency of filter plate cleaning, facilitates the maintenance and replacement of filter plates, ensures the stable operation of the ventilation system, and maintains the stable operation of the equipment through the cooling mechanism.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224401910U_ABST
    Figure CN224401910U_ABST
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Abstract

The utility model relates to technical field of machine room, concretely is a kind of efficient machine room, including machine room main body, and machine room main body is provided with ventilation duct, and ventilation duct is equipped with ventilation hole, and ventilation hole is fixedly provided with mounting bracket between fixed frame and filter plate, and mounting bracket is fixedly provided with motor one, and mounting bracket is rotatably provided with pivot close to filter plate side one, and the output shaft of motor one is transmission connection with pivot, and filter plate is equipped with through hole matched with pivot, and filter plate is equipped with fixed link away from mounting bracket side one, and pivot and fixed link are all fixedly provided with scraper, and scraper is abutted with filter plate, when pivot is rotated by motor one, can drive fixed link to rotate synchronously, so that the scraper on pivot and fixed link can simultaneously scrape the dust on both sides of filter plate, improve cleaning efficiency.
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Description

Technical Field

[0001] This application relates to the field of data center technology, specifically to a high-efficiency data center. Background Technology

[0002] A high-efficiency equipment room is a dedicated space for the centralized storage and management of critical infrastructure such as servers, network equipment, and storage systems. Its main functions include ensuring stable equipment operation, data storage and processing, and security protection. To ensure the stable operation of the equipment within the equipment room, ventilation equipment is typically installed.

[0003] In existing technologies, some computer rooms are usually equipped with ventilation ducts, which contain fans and filter plates. However, after long-term ventilation operations, dust tends to accumulate on the filter plates. Staff need to regularly disassemble and clean the filter plates to ensure effective filtration. Moreover, manual cleaning is inefficient and affects normal ventilation operations. Utility Model Content

[0004] To address the problem of low cleaning efficiency in existing technologies, this utility model provides a high-efficiency data center.

[0005] Therefore, the specific technical solution adopted by this utility model is as follows:

[0006] This utility model provides a high-efficiency data center, characterized by: including...

[0007] The main body of the computer room contains a working chamber. Ventilation ducts are installed on the main body, and ventilation holes are located within the ventilation ducts. A fixed frame is fixedly installed within each ventilation hole, and a fan is mounted on the fixed frame. A filter plate with filter holes is installed within the ventilation ducts. A mounting bracket is fixedly installed between the ventilation hole, the fixed frame, and the filter plate. A motor is fixedly mounted on the mounting bracket. A rotating shaft is rotatably mounted on the side of the mounting bracket closest to the filter plate. The output shaft of the motor is connected to the rotating shaft. Through holes that mate with the rotating shaft are provided on the filter plate. A fixed rod is located on the side of the filter plate furthest from the mounting bracket. Scrapers are fixedly mounted on both the rotating shaft and the fixed rod, and the scrapers abut against the filter plate.

[0008] It also includes a limiting mechanism, which is disposed on the fixed rod;

[0009] It also includes a cooling mechanism, which is located in the main body of the computer room.

[0010] Preferably, the limiting mechanism includes a lever, a plug rod, a slider, a connecting rod, and a spring. A countersunk hole is provided on the rotating shaft, a fixed rod is embedded in the countersunk hole, and the fixed rod has a mounting groove. The lever is slidably disposed in the mounting groove. A slot communicating with the mounting groove is provided on the side wall of the fixed rod, and a plug rod is slidably disposed in the slot. One end of the plug rod in the mounting groove has an inclined surface. The lever has an inclined groove that matches the inclined surface, and a groove is provided on the side wall of the groove. A sliding groove with the same inclination direction as the inclined groove is provided on the side wall of the groove. A slider is slidably disposed in the sliding groove, and one end of the slider is fixedly connected to the plug rod. A retaining groove matching the plug rod is provided on the inner wall of the countersunk hole. The connecting rod is fixedly disposed in the mounting groove. A round hole matching the connecting rod is provided on the lever. A spring is sleeved on the connecting rod, and both ends of the spring are respectively connected to the fixed rod. When connecting the fixed rod to the rotating shaft, press the lever on the fixed rod. The lever slides along the mounting groove and compresses the spring. The inclined surface and slider on the insertion rod cooperate with the inclined groove and sliding groove on the lever, causing the insertion rod to slide and retract along the groove. Then, insert the fixed rod into the countersunk hole of the rotating shaft. Release the lever, and the lever slides out of the mounting groove under the compression of the spring. This causes the insertion rod to slide out along the groove through the contact between the inclined groove and the inclined surface. This allows the end of the insertion rod away from the lever to be inserted into the slot in the countersunk hole, thus limiting the connection between the fixed rod and the rotating shaft. This allows the fixed rod to rotate synchronously when the rotating shaft rotates. The operation is convenient, and the fixed rod can be quickly installed and removed by pressing the lever.

[0011] Preferably, the cooling mechanism includes a cooler, a water pump, a delivery pipe, a pad, and a shelf. The pads are arranged in multiple sets and spaced apart at the bottom of the working chamber. The shelf is fixedly mounted on the pad and has ventilation holes. The cooler and the water pump are both fixedly mounted on the outside of the main body of the machine room. One end of the delivery pipe is connected to the outlet of the cooler through the water pump. The delivery pipe passes through the pad and the other end is connected to the inlet of the cooler. The cooler is a cooling tower or a dry cooler. The cooler is used to cool the circulating water delivered through the delivery pipe. Then, the water pump is used to drive the cooling water to circulate along the delivery pipe. When the cooling water flows along the delivery pipe in the working chamber, it cools the air around the pipe. When the ventilation duct is in operation, it gradually delivers low-temperature air from the bottom to the top, thereby cooling the electromechanical equipment on the shelf.

[0012] Preferably, the conveying pipe is arranged in an S-shape within the working chamber. The S-shaped conveying pipe can extend its length at the bottom of the placement plate, thereby improving the cooling effect on the air within the working chamber.

[0013] Preferably, the side wall of the countersunk hole is provided with a limiting groove that connects to the slot. When the fixing rod is inserted along the countersunk hole, by aligning the limiting groove with the rod, the rod can be quickly guided to the slot position, thereby improving the installation efficiency of the fixing rod.

[0014] Preferably, the insertion rods are arranged in two sets at intervals along the circumference of the fixed rod. The multiple sets of insertion rods provide multi-point limiting for the connection between the fixed rod and the rotating shaft, ensuring the stability of the connection between the fixed rod and the rotating shaft.

[0015] Preferably, the ventilation duct is provided with a clamping plate on one side outside the main body of the machine room, the filter plate is embedded in the opening of the ventilation hole, the side wall of the ventilation duct is provided with threaded holes, the filter plate is provided with connection holes one aligned with the threaded holes around its perimeter, and the clamping plate is provided with connection holes two aligned with connection holes one. By passing screws through the filter plate and the connection holes one and two on the clamping plate and then connecting them with the threaded holes, the filter plate can be installed and limited, making it easy to disassemble and replace the filter plate.

[0016] The advantages of adopting the above technical solution are:

[0017] 1. This utility model is equipped with a rotating shaft, a fixed rod, and a scraper. When the motor drives the rotating shaft to rotate, it can drive the fixed rod to rotate synchronously, so that the scraper on the rotating shaft and the fixed rod can scrape away the dust on both sides of the filter plate at the same time, thus improving the cleaning efficiency.

[0018] 2. By pressing the lever on the fixed rod, the staff can easily install and disassemble the fixed rod and the rotating shaft, and then disassemble the filter plate through the clamping plate, which is convenient for replacing and maintaining the filter plate. Attached Figure Description

[0019] To more clearly illustrate the technical solutions in the embodiments of this application, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the accompanying drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0020] Figure 1 A schematic diagram of the structure of this utility model is shown;

[0021] Figure 2 A partial cross-sectional view of the present invention is shown;

[0022] Figure 3 A partial cross-sectional view of the present invention is shown;

[0023] Figure 4 A partial structural schematic diagram of this utility model is shown;

[0024] Figure 5 A partial cross-sectional view of the present invention is shown;

[0025] Figure 6 A partial cross-sectional view of the present invention is shown.

[0026] The components include: 1. Main body of the machine room; 101. Working chamber; 102. Pad; 103. Shelf; 104. Ventilation hole; 2. Ventilation duct; 201. Ventilation hole; 202. Filter plate; 203. Filter hole; 204. Clamping plate; 3. Fixing frame; 301. Fan; 4. Mounting frame; 5. Rotating shaft; 501. Scraper; 502. Countersunk hole; 503. Limiting groove; 6. Fixing rod; 601. Mounting groove; 7. Pulling block; 701. Inclined groove; 702. Sliding groove; 8. Insert rod; 801. Slider; 802. Connecting rod; 803. Spring; 9. Cooler; 901. Conveying pipe. Detailed Implementation

[0027] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.

[0028] like Figure 1-6 As shown in the figure, this utility model discloses a high-efficiency computer room, including a computer room body 1, a limiting mechanism, and a cooling mechanism. The computer room body 1 has a working chamber 101. A ventilation duct 2 is installed on the computer room body 1, and a ventilation hole 201 is provided inside the ventilation duct 2. A fixing frame 3 is fixedly installed inside the ventilation hole 201, and a fan 301 is installed on the fixing frame 3. A filter plate 202 is installed inside the ventilation duct 2, and filter holes 203 are provided on the filter plate 202. The ventilation hole 201 is located between the fixing frame 3 and the filter plate 202. A mounting frame 4 is fixedly installed in the room, and a motor is fixedly installed on the mounting frame 4. A rotating shaft 5 is rotatably installed on the side of the mounting frame 4 near the filter plate 202. The output shaft of the motor is connected to the rotating shaft 5. The filter plate 202 is provided with a through hole that matches the rotating shaft 5. A fixing rod 6 is provided on the side of the filter plate 202 away from the mounting frame 4. Scrapers 501 are fixedly installed on both the rotating shaft 5 and the fixing rod 6. The scrapers 501 abut against the filter plate 202. The limiting mechanism is provided on the fixing rod 6. The cooling mechanism is provided in the main body 1 of the machine room.

[0029] In at least one embodiment, the limiting mechanism includes a lever 7, a rod 8, a slider 801, a connecting rod 802, and a spring 803. A countersunk hole 502 is provided on the rotating shaft 5, and a fixing rod 6 is embedded in the countersunk hole 502. The fixing rod 6 has a mounting groove 601, and the lever 7 is slidably disposed within the mounting groove 601. A slot communicating with the mounting groove 601 is provided on the side wall of the fixing rod 6, and the rod 8 is slidably disposed within the slot. One end of the rod 8 within the mounting groove 601 has a bevel. The lever 7... The upper part is provided with an inclined groove 701 that matches the inclined surface. The side wall of the inclined groove 701 is provided with a groove. The side wall of the groove is provided with a sliding groove 702 with the same inclination direction as the inclined groove 701. A slider 801 is slidably arranged in the sliding groove 702. One end of the slider 801 is fixedly connected to the insertion rod 8. The inner wall of the countersunk hole 502 is provided with a slot that matches the insertion rod 8. The connecting rod 802 is fixedly arranged in the mounting groove 601. The lever 7 is provided with a round hole that matches the connecting rod 802. The spring 803 is sleeved on the connecting rod 802. The two ends of the spring 803 are connected to the fixed rod 6 and the lever 7 respectively. When the fixed rod 6 is connected to the rotating shaft 5, the lever 7 on the fixed rod 6 is pressed. The lever 7 slides along the mounting groove 601 and compresses the spring 803. The inclined surface and the slider 801 on the insert rod 8 cooperate with the inclined groove 701 and the sliding groove 702 on the lever 7 to drive the insert rod 8 to slide and retract along the groove. Then the fixed rod 6 is inserted into the countersunk hole 502 of the rotating shaft 5. Then the lever 7 is released. The lever 7 slides out of the mounting groove 601 under the pressure of the spring 803. The inclined groove 701 and the inclined surface abut against each other to drive the insert rod 8 to slide out along the groove. Thus, the end of the insert rod 8 away from the lever 7 is inserted into the slot in the countersunk hole 502, realizing the connection limit of the fixed rod 6 and the rotating shaft 5. When the rotating shaft 5 rotates, it can drive the fixed rod 6 to rotate synchronously. The operation is convenient, and the fixed rod 6 can be quickly installed and removed by pressing the lever 7.

[0030] In at least one embodiment, the cooling mechanism includes a cooler 9, a water pump, a delivery pipe 901, a pad 102, and a shelf 103. Multiple sets of pads 102 are spaced apart at the bottom of the working chamber 101. The shelf 103 is fixedly mounted on the pads 102 and has ventilation holes 104. The cooler 9 and the water pump are both fixedly mounted on the outside of the main body 1 of the machine room. One end of the delivery pipe 901 is connected to the outlet of the cooler 9 via the water pump, and the delivery pipe 901 passes through the pad 102. 2. The other end is connected to the water inlet of the cooler 9, where the cooler 9 is a cooling tower or dry cooler. The cooler 9 is used to cool the circulating water transported through the conveying pipe 901. Then the water pump is used to drive the cooling water to circulate along the conveying pipe 901. When the cooling water flows along the conveying pipe 901 in the working chamber 101, it cools the air around the pipe. When the ventilation duct 2 is in ventilation operation, it gradually transports low-temperature air from the bottom to the top, thereby cooling the electromechanical equipment on the shelf 103.

[0031] In at least one embodiment, the delivery pipe 901 is arranged in an S-shape within the working chamber 101. The S-shaped delivery pipe 901 can extend its length at the bottom of the shelf 103, thereby improving the cooling effect on the air within the working chamber 101.

[0032] In at least one embodiment, the side wall of the countersunk hole 502 is provided with a limiting groove 503 that connects to the slot. When the fixing rod 6 is inserted along the countersunk hole 502, the limiting groove 503 is aligned with the insertion rod 8, which can quickly guide the insertion rod 8 to the slot position and improve the installation efficiency of the fixing rod 6.

[0033] In at least one embodiment, the insertion rods 8 are arranged in two sets at intervals along the circumference of the fixed rod 6. The multiple sets of insertion rods 8 provide multi-point limiting for the connection between the fixed rod 6 and the rotating shaft 5, ensuring the stability of the connection between the fixed rod 6 and the rotating shaft 5.

[0034] In at least one embodiment, a clamping plate 204 is provided on one side of the ventilation duct 2 outside the main body 1 of the machine room. The filter plate 202 is embedded in the opening of the ventilation hole 201. The side wall of the ventilation duct 2 is provided with threaded holes. The filter plate 202 is provided with a first connection hole aligned with the threaded holes around its perimeter. The clamping plate 204 is provided with a second connection hole aligned with the first connection hole. By passing screws through the first and second connection holes on the filter plate 202 and the clamping plate 204 and connecting them with the threaded holes, the filter plate 202 can be installed and limited, making it easy to disassemble and replace the filter plate 202.

[0035] In the main body 1 of the computer room, the electromechanical equipment is installed in the working chamber 101 inside the main body 1. During operation, the cooling mechanism on the main body 1 cools down the electromechanical equipment in the working chamber 101 to ensure stable operation. When ventilation is required, the fan 301 in the ventilation duct 2 is activated. The fan 301 transports the hot air in the working chamber 101 to the outside of the main body 1 of the computer room through the filter plate 202. The filter holes 203 on the filter plate 202 can isolate and adhere to dust and other impurities in the air, preventing external dust and other impurities from entering the working chamber 101 through the ventilation holes 201. When dust adheres to the filter plate 202... When dust and impurities are removed, the motor on the mounting bracket 4 is started. The output shaft of the motor drives the rotating shaft 5 to rotate. The scraper 501 rotates synchronously with the rotating shaft 5. Through the contact between the scraper 501 and the filter plate 202, the scraper 501 scrapes off the dust and other impurities attached to one side of the filter plate 202 when it rotates. The fixing rod 6 is connected to the rotating shaft 5 through a limiting mechanism. When the rotating shaft 5 rotates, it drives the fixing rod 6 to rotate synchronously. Thus, the fixing rod 6 and the scraper 501 on the rotating shaft 5 clean both sides of the filter plate 202 when they rotate, realizing the simultaneous cleaning of dust on both sides of the filter plate 202 and improving the cleaning efficiency.

[0036] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this application, and are not intended to limit them. Although this application has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions of the embodiments of this application.

Claims

1. A high-efficiency data center, characterized in that: include The main body of the computer room contains a working chamber. Ventilation ducts are installed on the main body, and ventilation holes are located within the ventilation ducts. A fixed frame is fixedly installed within each ventilation hole, and a fan is mounted on the fixed frame. A filter plate with filter holes is installed within the ventilation ducts. A mounting bracket is fixedly installed between the ventilation hole, the fixed frame, and the filter plate. A motor is fixedly mounted on the mounting bracket. A rotating shaft is rotatably mounted on the side of the mounting bracket closest to the filter plate. The output shaft of the motor is connected to the rotating shaft. Through holes that mate with the rotating shaft are provided on the filter plate. A fixed rod is located on the side of the filter plate furthest from the mounting bracket. Scrapers are fixedly mounted on both the rotating shaft and the fixed rod, and the scrapers abut against the filter plate. It also includes a limiting mechanism, which is disposed on the fixed rod; It also includes a cooling mechanism, which is located in the main body of the computer room.

2. The high-efficiency data center according to claim 1, characterized in that: The limiting mechanism includes a lever, a plug rod, a slider, a connecting rod, and a spring. A countersunk hole is provided on the rotating shaft, and a fixed rod is embedded in the countersunk hole. The fixed rod has an installation groove, and the lever is slidably disposed within the installation groove. A slot communicating with the installation groove is provided on the side wall of the fixed rod, and a plug rod is slidably disposed within the slot. One end of the plug rod within the installation groove has an inclined surface. The lever has an inclined groove that matches the inclined surface, and a groove is provided on the side wall of the inclined groove. A sliding groove with the same inclination direction as the inclined groove is provided on the side wall of the groove. A slider is slidably disposed within the sliding groove, and one end of the slider is fixedly connected to the plug rod. A retaining groove matching the plug rod is provided on the inner wall of the countersunk hole. The connecting rod is fixedly disposed within the installation groove, and a round hole matching the connecting rod is provided on the lever. A spring is sleeved on the connecting rod, and both ends of the spring are connected to the fixed rod and the lever, respectively.

3. The high-efficiency data center according to claim 1, characterized in that: The cooling mechanism includes a cooler, a water pump, a delivery pipe, a pad, and a shelf. Multiple sets of pads are spaced apart at the bottom of the working chamber. The shelf is fixedly mounted on the pad and has ventilation holes. The cooler and the water pump are both fixedly mounted on the outside of the main body of the machine room. One end of the delivery pipe is connected to the outlet of the cooler through the water pump. The delivery pipe passes through the pad and the other end is connected to the inlet of the cooler.

4. The high-efficiency data center according to claim 3, characterized in that: The delivery pipe is arranged in an S-shape within the working chamber.

5. A high-efficiency computer room according to claim 2, characterized in that: The sidewall of the countersunk hole is provided with a limiting groove for connecting the slot.

6. The high-efficiency computer room according to claim 2, characterized in that: The insertion rods are configured in two sets and arranged at intervals along the circumference of the fixed rod.

7. The high-efficiency computer room according to claim 2, characterized in that: The ventilation duct has a clamping plate on one side outside the main body of the machine room. The filter plate is embedded in the opening of the ventilation hole. The side wall of the ventilation duct has threaded holes. The filter plate has a first connection hole aligned with the threaded holes around its perimeter. The clamping plate has a second connection hole aligned with the first connection hole.