An automatic monitoring campus machine room device

The automatic monitoring system, which combines I-beam overhead rails and overhead rail robots, solves the problems of angle and pixel limitations of traditional monitoring devices, enabling multi-angle monitoring and efficient exhaust in campus computer rooms, thus improving equipment safety and environmental quality.

CN224368149UActive Publication Date: 2026-06-16HENAN SHANGZHI TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HENAN SHANGZHI TECH CO LTD
Filing Date
2025-06-24
Publication Date
2026-06-16

AI Technical Summary

Technical Problem

Traditional campus computer room monitoring devices are limited by monitoring angle and pixel limitations, making it difficult to fully observe the computer room environment, especially corners and remote areas, which leads to inconvenience in equipment security and environmental monitoring.

Method used

An automated monitoring system consisting of an I-beam overhead rail, a overhead rail robot, and a filter box, combined with environmental sensors, a pan-tilt camera, and a filter device, enables multi-angle mobile monitoring and airflow filtration. The overhead rail robot drives the pan-tilt camera to move, and combined with environmental sensor detection and fan exhaust, it achieves multi-angle monitoring and efficient exhaust.

🎯Benefits of technology

It enables multi-angle environmental monitoring and efficient exhaust within the computer room, improving equipment safety and environmental quality, enhancing the comprehensiveness and convenience of monitoring, and facilitating equipment maintenance.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of campus machine room devices of automatic monitoring, including I-shaped hanger rail, filter box and hanger rail robot, the top of the I-shaped hanger rail is fixedly installed with several hoisting parts by bolt, the bottom of the I-shaped hanger rail is equipped with several air inlet holes, the inside of the air inlet hole is movably inserted with gas-collecting cover, the inside of the I-shaped hanger rail is equipped with hollow groove, the inside of the hollow groove is movably installed with several environmental detection sensors;When carrying out exhaust, air flow is guided by first bellows and branch pipe and is guided by first support to divide air flow, and the inside of the multiple non-woven fabric filter core plates is guided by reducing local pressure, multi-layer filtration is carried out, so that dust is filtered more cleanly, and water vapor is absorbed by moisture absorption plate, so that air flow is processed, and non-woven fabric filter core plate and moisture absorption plate can be disassembled, cleaned and maintained by opening sealing box door.
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Description

Technical Field

[0001] This utility model relates to the field of campus computer room monitoring technology, specifically an automatic monitoring device for campus computer rooms. Background Technology

[0002] Campus computer labs are vital facilities for teaching, research, and other activities within a university. They are typically equipped with a large number of computers, network devices, and related auxiliary facilities. They provide students with a platform for computer courses, practical training, and various academic research activities, while also undertaking some of the university's information management tasks. The computer labs use monitoring systems to track equipment operation, environmental parameters, and security measures to ensure stable operation and equipment safety, thereby guaranteeing the smooth progress of teaching and research activities.

[0003] During the operation of equipment in campus computer labs, in order to protect the safety of the lab and the students using it, it is necessary to monitor the parameters of the lab environment, such as monitoring the air quality, including indicators such as dust and harmful gases. Excessive dust may affect the heat dissipation of the equipment, and harmful gases may corrode the equipment components. In addition, traditional monitoring is mostly fixed, which is limited by the monitoring angle. Corners and distant areas are difficult to observe completely due to pixel limitations, which causes certain inconveniences. Based on this, an automatic monitoring device for campus computer labs is proposed. Utility Model Content

[0004] The purpose of this invention is to provide an automatic monitoring device for campus computer rooms to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: an automatic monitoring device for a campus computer room, comprising an I-beam suspension rail, a filter box, and a suspension robot. Several lifting components are fixedly installed on the top of the I-beam suspension rail by bolts. Several air inlets are opened at the bottom of the I-beam suspension rail, and air collection hoods are movably inserted into the inner side of each air inlet. A hollow groove is opened inside the I-beam suspension rail, and several environmental detection sensors are movably installed inside the hollow groove. A pan-tilt monitoring camera is movably installed at the bottom of the suspension robot. A branch pipe is fixedly sleeved inside the bottom of the filter box, and the bottom end of the branch pipe is connected to a first corrugated pipe. Several guide holes are opened on the wall of the branch pipe, and several non-woven fabrics are movably sleeved on the outer side of the branch pipe. The filter core plate is equipped with a first bracket movably mounted at its bottom and a second bracket movably mounted at its top. A moisture-absorbing plate is movably mounted on the top of the second bracket. Several mounting components are fixedly mounted on the back of the filter box. A mounting cover is fixedly mounted on the top of the inner cavity of the filter box. A fan mounting bracket is fixedly mounted on the inner side of the mounting cover. An exhaust fan is bolted to the bottom of the fan mounting bracket. An aluminum foil ventilation pipe is connected to the top of the mounting cover. A fixed pipe is connected to the other end of the aluminum foil ventilation pipe. A sealing ring is movably fitted onto the outer side of the fixed pipe. A flange ring is movably fitted onto the outer side of the I-beam hanging rail. A sealed door is movably mounted on the front of the filter box via a hinge.

[0006] Preferably, the I-beam suspension rail is composed of multiple segments, the air inlets are evenly distributed in a circular linear pattern at the bottom of the I-beam suspension rail, the top of the air inlets is connected to the interior of the hollow groove, and the bottom of the first corrugated pipe is connected to the interior of the hollow groove.

[0007] Preferably, the environmental detection sensor includes a temperature and humidity sensor and a harmful gas detection sensor, and the environmental detection sensor is evenly distributed in a circular shape inside the hollow trough.

[0008] Preferably, the lifting components are evenly distributed in a circular linear pattern on the top of the I-beam suspension rail, and the drive unit of the suspension rail robot is movably mounted on the outside of the I-beam suspension rail.

[0009] Preferably, the flow guide holes are evenly distributed circumferentially inside the branch pipe, the first support and the non-woven filter core plate are evenly distributed in a linear staggered manner, and the first support and the non-woven filter core plate are evenly distributed in a linear staggered manner with the flow guide holes, and the non-woven filter core plate is movably sleeved on the outside of the branch pipe.

[0010] Preferably, the aluminum foil ventilation pipe passes through the filter box and extends to the outside of the filter box, and the sealing ring is sleeved on the outside of the fixed pipe by deformation extrusion.

[0011] Compared with the prior art, the beneficial effects of this utility model are as follows: When using this device, the user suspends the I-beam rail on the inside of the machine room wall using the hoisting parts and expansion bolts. During the hoisting process, the hoisting robot is connected to the I-beam rail. Then, the filter box is installed on the inside of the wall using the mounting parts. Finally, the fixed pipe is connected to the outside of the machine room through the exhaust hole. When running, the hoisting robot moves cyclically on the outside of the I-beam rail, carrying the pan-tilt monitoring camera. By moving on the inside of the machine room wall, it can monitor from multiple angles and adjust the monitoring position. When the environmental detection sensor detects a change in data, it starts the exhaust fan to discharge the airflow inside the filter box. The airflow is discharged through the aluminum foil ventilation pipe and the fixed pipe, and then rises and enters the hollow groove through the air inlet. Through the guide of the hollow groove, it enters the first corrugated pipe and the inside of the filter box, thereby exchanging and discharging the airflow and playing a role in equalizing the exhaust. This increases the discharge of dust and harmful gases, thereby increasing safety and facilitating monitoring and ventilation.

[0012] With the non-woven filter core plates and moisture-absorbing plates in place, when exhausting, the airflow is guided through the first corrugated pipe and branch pipe, and then evenly distributed and guided to the inner side of multiple non-woven filter core plates by the first bracket. This reduces local pressure and performs multi-layer filtration, thus filtering dust more cleanly. The moisture-absorbing plates absorb moisture, thereby processing the airflow. The non-woven filter core plates and moisture-absorbing plates can be disassembled, cleaned, and maintained by opening the sealed box door, and different arrangements can be replaced, further increasing the convenience of use. Attached Figure Description

[0013] Figure 1 This is a front-view stereoscopic structural diagram of the present utility model.

[0014] Figure 2 This is a schematic diagram of the three-dimensional appearance structure of the present invention from a rear-view or upward-looking perspective.

[0015] Figure 3 This is a schematic diagram of the right-side cross-sectional structure of this utility model.

[0016] Figure 4 This utility model Figure 3 Enlarged structural diagram at point A in the middle.

[0017] In the diagram: 1. I-beam suspension rail; 2. Lifting component; 3. Suspension robot; 4. First corrugated pipe; 5. Filter box; 6. Mounting component; 7. Sealed door; 8. Aluminum foil ventilation pipe; 9. Fixing pipe; 10. Flange ring; 11. Sealing ring; 12. Gas collection hood; 13. Pan-tilt monitoring camera; 14. Hollow groove; 15. Branch pipe; 16. First bracket; 17. Non-woven filter core plate; 18. Moisture-absorbing plate; 19. Second bracket; 20. Mounting cover; 21. Fan mounting bracket; 22. Exhaust fan; 23. Guide hole; 24. Environmental monitoring sensor; 25. Air inlet. Detailed Implementation

[0018] 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.

[0019] Please see Figures 1-4 This utility model provides a technical solution: an automatic monitoring campus computer room device, including an I-beam suspension rail 1, a filter box 5, and a suspension robot 3. Several lifting components 2 are fixedly installed on the top of the I-beam suspension rail 1 by bolts. Several air inlets 25 are opened at the bottom of the I-beam suspension rail 1, and a gas collection hood 12 is movably inserted into the inner side of each air inlet 25. A hollow groove 14 is opened inside the I-beam suspension rail 1, and several environmental detection sensors 24 are movably installed inside the hollow groove 14. A pan-tilt monitoring camera 13 is movably installed at the bottom of the suspension robot 3. A branch pipe 15 is fixedly sleeved inside the bottom of the filter box 5, and the bottom end of the branch pipe 15 is connected to a first corrugated pipe 4. Several guide holes 23 are opened on the wall of the branch pipe 15, and several non-woven filter cores are movably sleeved on the outer side of the branch pipe 15. The filter core plate 17 has a first bracket 16 movably installed at its bottom and a second bracket 19 movably placed at its top. A moisture-absorbing plate 18 is movably installed at the top of the second bracket 19. Several mounting parts 6 are fixedly installed on the back of the filter box 5. An installation cover 20 is fixedly installed at the top of the inner cavity of the filter box 5. A fan mounting bracket 21 is fixedly installed on the inner side of the installation cover 20. An exhaust fan 22 is bolted to the bottom of the fan mounting bracket 21. An aluminum foil ventilation pipe 8 is connected to the top of the installation cover 20. A fixed pipe 9 is connected to the other end of the aluminum foil ventilation pipe 8. A sealing ring 11 is movably sleeved on the outside of the fixed pipe 9. A flange ring 10 is movably sleeved on the outside of the I-beam hanging rail 1. A sealed box door 7 is movably installed on the front of the filter box 5 via a hinge.

[0020] The working principle of the above technical solution is as follows: During use, the operator uses the hoisting component 2 and expansion bolts to hoist the I-beam rail 1 onto the inside of the machine room wall. During the hoisting process, the rail-mounting robot 3 is connected to the I-beam rail 1. Then, the filter box 5 is installed on the inside of the wall using the mounting component 6. Finally, the fixing pipe 9 is connected to the outside of the machine room through the exhaust port. When in operation, the rail-mounting robot 3 moves cyclically on the outside of the I-beam rail 1, carrying the pan-tilt monitoring camera 13. By moving along the inside of the machine room wall, multi-angle monitoring is achieved. The monitoring position is adjusted, and when the environmental detection sensor 24 detects a data change, the exhaust fan 22 is started to exhaust the airflow inside the filter box 5. The airflow is discharged through the aluminum foil ventilation pipe 8 and the fixed pipe 9, and then enters the hollow trough 14 through the air inlet 25. The airflow is guided into the first corrugated pipe 4 and the filter box 5 through the hollow trough 14, thereby exchanging and discharging the airflow and achieving balanced exhaust. This increases the discharge of dust and harmful gases, thereby increasing safety and facilitating monitoring and air exchange.

[0021] In another implementation scheme, such as Figures 1-3 As shown, the I-beam hanging rail 1 is composed of multiple segments. The air inlet 25 is evenly distributed in a circular linear pattern at the bottom of the I-beam hanging rail 1. The top of the air inlet 25 is connected to the interior of the hollow groove 14, and the bottom of the first corrugated pipe 4 is connected to the interior of the hollow groove 14.

[0022] The multi-segment splicing of the I-beam hanging rail 1 facilitates transportation and installation, and the hanging rail robot 3 is assembled. The air inlet 25 facilitates air intake, and the air collection hood 12 is inserted for easy air intake. The gap between the drive unit of the hanging rail robot 3 and the bottom of the I-beam hanging rail 1 facilitates the installation of the air collection hood 12 without obstructing operation. The hollow trough 14 guides the airflow to the inside of the first corrugated pipe 4, which facilitates balanced airflow through the hollow trough 14, thereby forming a relatively balanced exhaust effect in the machine room.

[0023] In another implementation scheme, such as Figure 3 As shown, the environmental detection sensor 24 includes a temperature and humidity sensor and a harmful gas detection sensor. The environmental detection sensor 24 is arranged in a circular, linear, and uniform manner inside the hollow groove 14.

[0024] The environmental detection sensor 24 can be replaced according to actual usage needs, such as installation in classrooms and computer rooms. It can be installed between temperature and humidity sensors and harmful gas sensors, and can sense the environment efficiently, which is convenient for subsequent use.

[0025] In another implementation scheme, such as Figures 1-3 As shown, the lifting components 2 are evenly distributed in a circular linear pattern on the top of the I-beam lifting rail 1, and the drive unit of the lifting robot 3 is movably installed on the outside of the I-beam lifting rail 1.

[0026] The suspended robot 3 includes a rotation mechanism comprising a drive module, a suspension rotation device, and an attitude adjustment component. The drive module suspends the robot body on an I-beam rail. The drive component is connected to a drive motor. The controller controls the drive module to independently rotate by adapting to the curvature of the rail through the attitude adjustment component, enabling the robot to move automatically on the I-beam rail 1. The suspended robot 3 mainly includes the following mechanical structure: a shell, generally made of stainless steel or other materials, including a hook and shell section; a support frame, used to support other parts of the robot and serving as the main load-bearing structure; active and passive rollers, where the active rollers, under the control of servo motors, enable the robot to move forward, backward, and turn, while the passive rollers assist in supporting and guiding the robot's movement on the rail. The second part is the drive and control system: a servo motor, which controls the steering and stepping speed of the active rollers, precisely controlling the robot's movement; and a brake motor, used to control the robot's stopping, ensuring the robot can stop accurately when needed. The main controller, acting as the robot's "brain," is responsible for controlling all of the robot's modules, including collecting real-time status and log information, and controlling the movements of components such as active rollers, lifting systems, and cameras. The battery powers the active servo motors, brake motors, observation modules, communication modules, and positioning modules, and monitors remaining battery power in real time. The third part is the detection and perception section: The observation module typically includes high-precision cameras, infrared thermal imaging equipment, and various environmental sensors to collect environmental information about the robot's path. The positioning module collects real-time position data to help the robot determine its position on the track, achieving precise positioning and navigation. The fourth part is the communication and alarm section: The communication module is responsible for data transmission between the robot and the host computer or other devices, enabling remote monitoring and control. The sound, light, and electrical alarm emits alarm signals through sound and light when the robot detects an abnormal situation, alerting nearby personnel.

[0027] In another implementation scheme, such as Figure 3 and Figure 4 As shown, the flow guide holes 23 are evenly distributed in a circular pattern inside the branch pipe 15. The first support 16 and the non-woven filter core plate 17 are evenly distributed in a linear staggered manner, and the first support 16 and the non-woven filter core plate 17 are evenly distributed in a linear staggered manner with the flow guide holes 23. The non-woven filter core plate 17 is movably sleeved on the outside of the branch pipe 15.

[0028] With the non-woven filter core plate 17 and the moisture-absorbing plate 18 in place, when exhausting, the airflow is guided through the first corrugated pipe 4 and the branch pipe 15 and evenly distributed to the inner side of multiple non-woven filter core plates 17 by the first bracket 16. This reduces local pressure and performs multi-layer filtration, thus filtering dust more cleanly. The moisture-absorbing plate 18 absorbs moisture, thus processing the airflow. The non-woven filter core plate 17 and the moisture-absorbing plate 18 can be disassembled, cleaned, and maintained by opening the sealed box door 7, and different arrangements can be replaced, further increasing the ease of use. The moisture-absorbing plate 18 can be replaced with a dehumidifier. When the fan mounting bracket 21 reduces its speed, the airflow speed decreases, allowing for moisture absorption and facilitating filtration.

[0029] In another implementation scheme, such as Figures 1-3 As shown, the aluminum foil ventilation pipe 8 passes through the filter box 5 and extends to the outside of the filter box 5, and the sealing ring 11 is sleeved on the outside of the fixed pipe 9 by deformation and extrusion.

[0030] The aluminum foil ventilation duct 8 and the fixed duct 9 work together to facilitate the exhaust airflow to the outside. At the same time, it can be drawn out through the fixed duct 9 and introduced into the room to purify the indoor air. The exhaust position of the fixed duct 9 can be placed indoors or outdoors as needed to ensure the exhaust effect.

[0031] 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. An automatic monitoring device for a campus computer room, comprising an I-beam overhead rail (1), a filter box (5), and an overhead rail robot (3), characterized in that: The top of the I-beam hanging rail (1) is fixedly installed with several lifting components (2) by bolts. The bottom of the I-beam hanging rail (1) is provided with several air inlets (25). An air collection hood (12) is movably inserted into the inner side of the air inlet (25). The interior of the I-beam hanging rail (1) is provided with a hollow groove (14). Several environmental detection sensors (24) are movably installed inside the hollow groove (14). A pan-tilt monitoring camera (13) is movably installed at the bottom of the hanging rail robot (3). A branch pipe (15) is fixedly sleeved inside the bottom end of the filter box (5). The bottom end of the branch pipe (15) is connected to a first corrugated pipe (4). Several guide holes (23) are provided on the pipe wall of the branch pipe (15). Several non-woven filter core plates (17) are movably sleeved on the outer side of the branch pipe (15). A first bracket (1) is movably installed at the bottom of the non-woven filter core plate (17). 6) A second bracket (19) is movably placed on the top of the non-woven filter core plate (17), and a moisture-absorbing plate (18) is movably installed on the top of the second bracket (19). Several mounting parts (6) are fixedly installed on the back of the filter box (5). An installation cover (20) is fixedly installed on the top of the inner cavity of the filter box (5). A fan mounting bracket (21) is fixedly installed on the inner side of the installation cover (20). An exhaust fan (22) is bolted to the bottom of the fan mounting bracket (21). An aluminum foil ventilation pipe (8) is connected to the top of the installation cover (20). A fixed pipe (9) is connected to the other end of the aluminum foil ventilation pipe (8). A sealing ring (11) is movably sleeved on the outer side of the fixed pipe (9). A flange ring (10) is movably sleeved on the outer side of the I-beam hanging rail (1). A sealed box door (7) is movably installed on the front of the filter box (5) through a hinge.

2. The campus computer room automatic monitoring device according to claim 1, characterized in that: The I-beam suspension rail (1) is composed of multiple segments. The air inlet (25) is evenly distributed in a circular linear pattern at the bottom of the I-beam suspension rail (1). The top of the air inlet (25) is connected to the interior of the hollow groove (14). The bottom of the first corrugated pipe (4) is connected to the interior of the hollow groove (14).

3. The campus computer room automatic monitoring device according to claim 1, characterized in that: The environmental detection sensor (24) includes a temperature and humidity sensor and a harmful gas detection sensor. The environmental detection sensor (24) is circularly and linearly distributed inside the hollow groove (14).

4. The campus computer room automatic monitoring device according to claim 1, characterized in that: The lifting components (2) are evenly distributed in a circular linear pattern on the top of the I-beam lifting rail (1), and the drive unit of the lifting rail robot (3) is movably installed on the outside of the I-beam lifting rail (1).

5. The campus computer room automatic monitoring device according to claim 1, characterized in that: The flow guide holes (23) are evenly distributed in a circular pattern inside the branch pipe (15). The first support (16) and the non-woven filter core plate (17) are evenly distributed in a linear staggered manner. The first support (16) and the non-woven filter core plate (17) are evenly distributed in a linear staggered manner with the flow guide holes (23). The non-woven filter core plate (17) is movably sleeved on the outside of the branch pipe (15).

6. The campus computer room automatic monitoring device according to claim 1, characterized in that: The aluminum foil ventilation pipe (8) passes through the filter box (5) and extends to the outside of the filter box (5), and the sealing ring (11) is sleeved on the outside of the fixed pipe (9) by deformation extrusion.