A data center computer room dehumidification equipment

By installing serpentine air intake ducts and foot pedals on the floor of the data center server room, combined with fan suction and filter box filtration, the problem of uneven dehumidification on the server room floor was solved, achieving efficient dehumidification and air purification.

CN224462519UActive Publication Date: 2026-07-07SHENZHEN POLYTECHNIC

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN POLYTECHNIC
Filing Date
2025-06-18
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

In existing technologies, the dehumidification effect of the floor in data center computer rooms is poor, especially since humid air accumulates below and cannot be directly sucked in by the fan, resulting in uneven dehumidification.

Method used

A dehumidification device was designed, comprising a fan, a corrugated pipe, an air inlet duct, and a foot pedal. The air inlet duct is laid on the ground in a serpentine structure and has a foot pedal and foot pad. The fan draws in humid air, and the foot pedal and foot pad are used to prevent people from stepping on it. The foot pad absorbs moisture, and together with the filter box, it filters impurities, thereby improving the dehumidification effect of the ground.

Benefits of technology

It achieves efficient dehumidification of the computer room floor, prevents personnel from stepping on equipment, purifies the air, reduces air pollution, and improves dehumidification efficiency and effectiveness.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a data center computer lab dehumidification equipment belongs to data center computer lab field, a data center computer lab dehumidification equipment, including fan, the one side of fan is installed with at least one bellows, and the one end of bellows away from fan all installs and enters the air pipe, and the one end of air inlet pipe is all closed structure, and the air inlet pipe part all presents the serpentine structure and is set up with a plurality of air inlet hole in this serpentine structure, and the upper surface of air inlet pipe serpentine structure presents all set up and treads the board, and the lower surface of tread board is along horizontal array distribution with a plurality of baffle, and the lower end of baffle all passes through the clearance of corresponding air inlet pipe serpentine structure, and the upper surface of tread board all installs and foot pad, and the edge fixed mounting of fan is communicated with the filter box of bellows one end, it can realize, and the damp air of suction computer lab ground, and use foot pad to absorb the moisture of staff foot and bring into computer lab, is favorable to improve ground dehumidification effect.
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Description

Technical Field

[0001] This utility model relates to the field of data center computer rooms, and more specifically, to a dehumidification device for data center computer rooms. Background Technology

[0002] Data center server rooms are places that provide storage and network equipment. People entering and leaving can easily bring in moisture, especially on rainy days. Rainwater stuck to shoes can enter the server room, causing increased humidity. Generally, fans are added to the walls of the server room to remove moisture by increasing exhaust air.

[0003] Patent search revealed that Chinese patent CN218944603U discloses a dehumidification device for data center computer rooms, including a dehumidification device body, an air inlet, an extension plate, a slide plate, a slider, a connecting rod, a hand-tightening bolt, an air outlet, a fan, a pull-out box, a spring, a crossbar, a support rod, and brushes. Although it uses a fan to blow air and a filter plate to filter dust from the air, the connecting rod is manually operated to drive the slider and the brushes on the support rod on the crossbar to perform dust removal. This helps to improve the dehumidification efficiency of the dehumidification device and saves manual cleaning time.

[0004] However, the aforementioned patent dehumidifies by drawing humid air through the air inlet with a fan and cleaning it with brushes. Humid air usually accumulates below the data center server room, especially on the ground, and cannot be directly exposed to the wind, resulting in poor dehumidification of the ground. To address this, we propose a dehumidification device for data center server rooms. Utility Model Content

[0005] Technical problems to be solved

[0006] To address the problems existing in the prior art, the purpose of this utility model is to provide a dehumidification device for data center computer rooms. It can extract humid air from the floor of the computer room and absorb moisture brought into the computer room by the staff's feet using foot pads, which helps to improve the dehumidification effect of the floor.

[0007] Technical solution

[0008] To solve the above problems, the present invention adopts the following technical solution.

[0009] A dehumidification device for a data center server room includes a fan. At least one corrugated pipe is installed on one side of the fan. An air inlet pipe is installed at the end of the corrugated pipe furthest from the fan. One end of each air inlet pipe is closed. Each air inlet pipe has a serpentine structure with multiple air intake holes. A foot pedal is installed on the upper surface of each serpentine air inlet pipe. Multiple baffles are arranged in a horizontal array on the lower surface of each foot pedal. The lower ends of the baffles pass through the gaps in the corresponding serpentine air inlet pipe structure. Foot pads are installed on the upper surface of each foot pedal. The serpentine air inlet structure can be laid flat on the server room floor, surrounding the data center server units. The foot pedals and foot pads stand on top of the serpentine structure, forming a foot-feeding structure. When the fan is turned on, it draws in humid air from the server room floor. Workers can walk on the foot-feeding structure, which also prevents them from stepping on the corrugated pipes and air inlet pipes. The foot pads absorb moisture brought into the server room by workers' feet, thus improving the dehumidification effect.

[0010] Furthermore, a filter box connected to one end of a corrugated pipe is fixedly installed on the edge of the fan. A mesh cloth is fixedly installed on the inner side of the filter box. When exhausting, humid air enters the filter box and is filtered by the mesh cloth to remove dust and other impurities, thereby purifying the air and reducing pollution.

[0011] Furthermore, clamps are fitted on the outer side of the air inlet pipe near the corresponding corrugated pipe. The clamps are fixed to the designated position on the wall with screws to tighten the air inlet pipe and provide support.

[0012] Furthermore, perforated plates are fixedly installed between the two ends of the two adjacent partitions. The lower surface of each perforated plate is perforated and is fitted onto the outside of the corresponding serpentine structure of the air inlet pipe. The two perforated plates support the serpentine structure of the air inlet pipe from both sides to prevent the air inlet pipe from sticking to the side of the partition and causing the air inlet to be blocked.

[0013] Furthermore, flat-head screws are installed through the four corners of the upper surface of the foot pad, and the lower ends of the flat-head screws are connected to the upper surface of the corresponding foot pedal. The flat-head screws are used to tighten the four corners of the upper surface of the foot pad and the upper surface of the corresponding foot pedal, thereby improving the stability of the foot pad and preventing the foot pad from being kicked off.

[0014] Furthermore, at least one diversion pipe is installed through the outside of the filter box to absorb humid air above the machine room. This diversion pipe, combined with the air inlet, increases the area for absorbing humid air and further improves the dehumidification efficiency.

[0015] Beneficial effects

[0016] Compared with existing technologies, the advantages of this utility model are:

[0017] (1) In this solution, the serpentine structure of the air intake duct is laid flat on the floor of the computer room and can surround the data center unit. Then, the partition is inserted into the gap of the corresponding serpentine structure to support the foot pedal. The foot pedal and foot pad stand on the serpentine structure to form a foot pedal structure. After the fan is turned on, the humid air on the floor of the computer room is drawn along the corrugated pipe, air intake duct and air inlet. The staff can walk on the foot pedal structure, which can also prevent the staff from stepping on the corrugated pipe and air intake duct. The foot pad absorbs the moisture brought into the computer room by the staff's feet, which is conducive to improving the dehumidification effect of the floor.

[0018] (2) When exhausting air, the humid air enters the filter box and is filtered by the mesh cloth to remove dust and other impurities, thereby purifying the air and reducing pollution to the atmosphere. Attached Figure Description

[0019] Figure 1 This is a schematic diagram of the structure from the front view of this utility model;

[0020] Figure 2 This is a cross-sectional structural schematic diagram of the present invention;

[0021] Figure 3 For the present utility model Figure 2 Enlarged structural diagram at point A;

[0022] Figure 4 For the present utility model Figure 2 A magnified structural diagram at point B in the middle.

[0023] Explanation of the labels in the diagram:

[0024] 1. Fan; 2. Corrugated pipe; 3. Air inlet pipe; 4. Air inlet vent; 5. Foot pedal; 6. Partition; 7. Foot pad; 8. Filter box; 9. Mesh fabric; 10. Clamp; 11. Perforated plate; 12. Flathead screw; 13. Diverter pipe. Detailed Implementation

[0025] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the protection scope of the present utility model.

[0026] Example:

[0027] Please see Figure 1-4A dehumidification device for a data center server room includes a fan 1. At least one corrugated pipe 2 is installed on one side of the fan 1. An air inlet pipe 3 is installed at the end of each corrugated pipe 2 away from the fan 1. The other end of each corrugated pipe 2 is bonded to one side of the fan 1. One end of each air inlet pipe 3 is a closed structure, and the other end is fixedly connected to one end of each corrugated pipe 2 via a connector. Each portion of the air inlet pipe 3 has a serpentine structure with multiple air inlet holes 4. A foot pedal 5 is provided on the upper surface of each serpentine structure of the air inlet pipe 3. Multiple baffles 6 are distributed in a horizontal array on the lower surface of each foot pedal 5. The upper surface of each baffle 6 is bonded to the lower surface of the corresponding foot pedal 5. The lower end of each baffle 6 passes through the gap in the serpentine structure of the corresponding air inlet pipe 3. A [missing information - likely a continuation of the previous point] is installed on the upper surface of each foot pedal 5. Foot pads 7 are made of felt and are absorbent. The lower surface of foot pads 7 is adhered to the upper surface of the corresponding foot pedals 5. First, the fan 1 is embedded in the ventilation opening of the data center server room. When working, the serpentine structure of the air inlet duct 3 is laid flat on the floor of the server room to surround the data center server units. Then, the partition 6 is inserted into the gap of the corresponding serpentine structure to support the foot pedals 5. The foot pedals 5 and foot pads 7 stand on top of the serpentine structure to form a footing structure. After the fan 1 is turned on, it draws humid air from the server room floor along the corrugated pipe 2, air inlet duct 3 and air inlet hole 4. Staff can walk on the footing structure, which also prevents staff from stepping on the corrugated pipe 2 and air inlet duct 3. The foot pads 7 absorb the moisture brought into the server room by the staff's feet, which helps to improve the dehumidification effect of the floor.

[0028] See Figure 2 and Figure 3 A filter box 8, which is connected to one end of a corrugated pipe 2, is fixedly installed on the edge of the fan 1. The filter box 8 has an opening on one side and is fixedly connected to the edge of the fan 1 by screws. A mesh cloth 9 is fixedly installed on the inside of the filter box 8, and the edge of the mesh cloth 9 is fixedly connected to the inside of the filter box 8 by screws. When exhausting, humid air enters the filter box 8 and is filtered by the mesh cloth 9 to remove dust and other impurities, thereby purifying the air and reducing pollution to the atmosphere.

[0029] See Figure 1 and Figure 2 Each air inlet pipe 3 is fitted with a clamp 10 near the corresponding corrugated pipe 2 on its outer side. The inner side of the clamp 10 is fitted on the outer side of the corresponding air inlet pipe 3. The clamp 10 is fixed to the designated position on the wall with screws to tighten the air inlet pipe 3 and provide support.

[0030] See Figure 2 and Figure 4A perforated plate 11 is fixedly installed between the two ends of two adjacent partitions 6. The height of the perforated plate 11 is less than the height of the partition 6 so as to leave space for air circulation with the ground. The two ends of the perforated plate 11 are fixedly connected to one end of the corresponding two partitions 6 by bolts. The lower surface of the perforated plate 11 is perforated and is fitted onto the outside of the serpentine structure of the corresponding air inlet pipe 3. The two perforated plates 11 support the serpentine structure of the air inlet pipe 3 from both sides to prevent the air inlet pipe 3 from sticking to the side of the partition 6 and causing the air inlet hole 4 to be blocked.

[0031] See Figure 2 and Figure 4 Flat-head screws 12 are installed through the four corners of the upper surface of the foot pad 7. The lower ends of the flat-head screws 12 are connected to the upper surface of the corresponding foot pedal 5. The flat-head screws 12 are used to tighten the four corners of the upper surface of the foot pad 7 and the upper surface of the corresponding foot pedal 5 respectively, thereby improving the stability of the foot pad 7 and preventing the foot pad 7 from being kicked off.

[0032] See Figure 1 and Figure 3 At least one diversion pipe 13 is installed through the outside of the filter box 8. One end of the diversion pipe 13 extends into the interior of the filter box 8. The diversion pipe 13 is used to absorb the humid air above the machine room. In conjunction with the air inlet 4, the area for absorbing humid air is increased, thereby further improving the dehumidification efficiency.

[0033] Working principle: During operation, the serpentine structure of the air inlet duct 3 is laid flat on the floor of the computer room to surround the data center units. Then, the partition 6 is inserted into the gaps of the corresponding serpentine structure to support the foot pedal 5. The foot pedal 5 and the foot pad 7 stand on top of the serpentine structure to form a footing structure. After the fan 1 is started, it draws in the humid air from the floor of the computer room along the corrugated pipe 2, air inlet duct 3 and air inlet 4. The staff can walk on the footing structure, which also prevents the staff from stepping on the corrugated pipe 2 and air inlet duct 3. The foot pad 7 absorbs the moisture brought into the computer room by the staff's feet.

[0034] During exhaust, humid air enters the filter box 8 and is filtered by the mesh cloth 9 to remove dust and other impurities, thus purifying the air and reducing pollution to the atmosphere.

[0035] The above description is merely a preferred embodiment of this utility model; however, the protection scope of this utility model is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the technical scope disclosed in this utility model, based on the technical solution and its improved concept, should be included within the protection scope of this utility model.

Claims

1. A dehumidification device for a data center computer room, comprising a fan (1), characterized in that: At least one corrugated pipe (2) is installed on one side of the fan (1). An air inlet pipe (3) is installed on the end of the corrugated pipe (2) away from the fan (1). One end of the air inlet pipe (3) is a closed structure. The air inlet pipe (3) is a serpentine structure with multiple air inlets (4). A foot pedal (5) is provided on the upper surface of the serpentine structure of the air inlet pipe (3). Multiple partitions (6) are distributed in a horizontal array on the lower surface of the foot pedal (5). The lower end of each partition (6) passes through the gap of the serpentine structure of the corresponding air inlet pipe (3). A foot pad (7) is installed on the upper surface of the foot pedal (5).

2. The dehumidification equipment for data center computer rooms according to claim 1, characterized in that: A filter box (8) connected to one end of a corrugated pipe (2) is fixedly installed on the edge of the fan (1), and a mesh cloth (9) is fixedly installed on the inner side of the filter box (8).

3. The dehumidification equipment for data center computer rooms according to claim 1, characterized in that: The air inlet pipe (3) is fitted with clamps (10) on the outside of the corresponding corrugated pipe (2).

4. A dehumidification device for a data center computer room according to claim 1, characterized in that: A perforated plate (11) is fixedly installed between the two ends of the two adjacent partitions (6). The lower surface of the perforated plate (11) is perforated and is fitted onto the outside of the serpentine structure of the corresponding air inlet pipe (3).

5. A dehumidification device for a data center computer room according to claim 1, characterized in that: Flat-head screws (12) are installed through the four corners of the upper surface of the foot pad (7), and the lower ends of the flat-head screws (12) are connected to the upper surface of the corresponding foot pedal (5).

6. A dehumidification device for a data center computer room according to claim 2, characterized in that: At least one diversion pipe (13) is installed through the outside of the filter box (8).