A gimbal big data server cabinet for a computer
By combining a dynamic cooling system and a lifting mechanism in the server rack, real-time monitoring of the temperature inside the server rack and directional forced air cooling are achieved, solving the problems of uneven heat dissipation and energy waste under the traditional static cooling method, improving heat dissipation efficiency and simplifying the movement of the server rack.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- HENAN INST OF FINANCE & ECONOMICS
- Filing Date
- 2026-03-13
- Publication Date
- 2026-07-14
AI Technical Summary
Traditional server racks rely on static cooling methods, which are ill-suited to address localized hotspots caused by dynamic changes in equipment load. This results in uneven cooling, energy waste, and an inability to precisely cool specific devices.
A server rack combining a dynamic heat dissipation system and a built-in lifting and moving mechanism is designed. By combining the dynamic heat dissipation system with the built-in lifting and moving mechanism, a new device is used. A static heat dissipation method is employed, using a hydraulic rod drive motor. Drive motor 401 and exhaust fan 406 are fixedly connected to lead screws on both sides. Each of the three drive motors has a drive shaft fixedly connected to a lead screw 402. The outer walls of the three lead screws 402 are respectively threaded to a first equipment rack 403, a second equipment rack 404, and a third equipment rack 405. Exhaust fans 406 are embedded and fixedly connected inside each of the three equipment racks 403, 404, and 405. Temperature sensing modules 407 are fixedly connected to both sides of each exhaust fan 406.
It enables real-time monitoring of temperature distribution within the server rack and directional forced air cooling, improving heat dissipation efficiency, saving energy, and eliminating the need to disassemble internal equipment when moving the server rack, saving manpower and time.
Smart Images

Figure CN122395887A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of server rack technology, specifically to a PTZ big data server rack for computers. Background Technology
[0002] With the rapid development of cloud computing and big data technologies, server equipment, as the core of their physical infrastructure, is evolving towards high-density, large-scale cluster deployment. Servers generate a lot of heat during operation, and if heat dissipation is not timely, it will lead to decreased equipment performance, shortened lifespan, or even system crashes. Ensuring that they operate in a suitable temperature environment is crucial.
[0003] Traditional server racks often use fixed fan walls or integrated air conditioning ducts for heat dissipation. This static heat dissipation method is difficult to deal with the local "hot spots" caused by dynamic changes in equipment load, which can easily lead to uneven heat dissipation, energy waste, and inability to accurately cool specific overheated units.
[0004] Therefore, we propose to design a PTZ big data server cabinet for computers. Summary of the Invention
[0005] The purpose of this section is to outline some aspects of the embodiments of the present invention and to briefly describe some preferred embodiments. Simplifications or omissions may be made in this section, as well as in the abstract and title of this application, to avoid obscuring the purpose of these documents; however, such simplifications or omissions should not be construed as limiting the scope of the invention.
[0006] To address the aforementioned technical problems, according to one aspect of the present invention, the present invention provides the following technical solution: A PTZ big data server cabinet for computers includes a server cabinet body, a cabinet door connected to one side of the server cabinet body by a hinge, an operation panel embedded and fixedly connected to the top of the cabinet door, a cooling mechanism inside the server cabinet body, a base fixedly connected to the bottom of the server cabinet body, and a lifting mechanism fixedly connected inside the base. The cooling mechanism includes three drive motors embedded and fixed inside the base. Each of the three drive motors has a lead screw fixedly connected to its drive shaft. The outer walls of the three lead screws are respectively threaded to a first equipment frame, a second equipment frame, and a third equipment frame. Each of the first equipment frame, the second equipment frame, and the third equipment frame has an exhaust fan embedded and fixedly connected inside. Temperature sensing modules are fixedly connected to both sides of each exhaust fan.
[0007] Preferably, the lifting mechanism includes a fixed base with insert blocks on both sides. A base is located inside the fixed base, and self-locking casters are fixedly connected to the four corners of the base. A hydraulic rod is fixedly connected to the top of the fixed base. Before use, the hydraulic rod is connected to an external oil pump. The hydraulic rod lowers the base within the fixed base, allowing the self-locking casters to contact the ground instead of the base's bottom surface. This allows the server cabinet to be moved without disassembling the cloud-based big data server inside the cabinet, saving both manpower and significant time.
[0008] Preferably, slide rails are fixedly connected to both sides of the inner wall of the server cabinet, and sliders are fixedly connected to both sides of the first, second, and third equipment racks, with the sliders slidably connected to the slide rails. Regardless of which lead screw rotates, the first, second, and third equipment racks corresponding to that lead screw can move and rise along the slide rails.
[0009] Preferably, the first, second, and third equipment racks are evenly distributed inside the server cabinet. The first, second, and third equipment racks are located in the upper, middle, and lower areas of the cabinet, respectively, and can be moved to cover the location areas of all servers.
[0010] Preferably, the inner wall of the fixed base has limit grooves on both sides, and the outer wall of the base has limit strips corresponding to the limit grooves fixedly connected to both sides. The limit strips are slidably connected to the inner wall of the limit grooves. The limit strips can slide in the limit grooves, which facilitates limiting the lifting position of the fixed base.
[0011] Preferably, the outer wall of the fixing base has receiving grooves on both sides, and a spring assembly is fixedly connected between the receiving grooves and the insert block. The inner side wall of the base has a through hole corresponding to the insert block. The spring force of the spring assembly can drive the insert block to pass through the through hole and extend outward, which facilitates the assembly of the fixing base.
[0012] Preferably, a first ventilated mesh panel is bolted to the side of the server cabinet away from the cabinet door, and a second ventilated mesh panel is provided on the top and side walls of the lifting mechanism. The first and second ventilated mesh panels facilitate air circulation inside the cabinet, increasing heat dissipation and cooling efficiency.
[0013] Preferably, the temperature sensing module includes a wireless signal transceiver module and three temperature sensing probes. The three temperature sensing probes are distributed at the middle height of the first, second, and third equipment racks. When the first, second, and third equipment racks move, the corresponding temperature sensing probes can be moved. The multiple temperature sensing probes are evenly distributed on their respective equipment racks, which facilitates temperature monitoring of servers at the same height.
[0014] Compared with the prior art, the beneficial effects of the present invention are: This invention integrates a dynamic heat dissipation system with a built-in lifting and moving mechanism within the same cabinet. The system can monitor the temperature distribution at different heights within the cabinet in real time. Once a localized overheating area is identified, the fan can be activated for directional forced air cooling. Compared to traditional fixed heat dissipation systems, this not only saves energy but also provides more targeted cooling, significantly improving heat dissipation efficiency. Simultaneously, Attached Figure Description
[0015] To more clearly illustrate the technical solutions of the embodiments of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and detailed embodiments. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Wherein: Figure 1 This is a schematic diagram of the appearance of a PTZ big data server cabinet for a computer according to the present invention. Figure 2 This is a schematic diagram of the structure of a PTZ big data server cabinet for a computer according to the present invention. Figure 3 This is a schematic diagram of a cooling mechanism for a PTZ big data server cabinet for computers according to the present invention. Figure 4 This is a schematic diagram of a lifting mechanism for a PTZ big data server cabinet for computers according to the present invention. Figure 1 ; Figure 5 This is a schematic diagram of a lifting mechanism for a PTZ big data server cabinet for computers according to the present invention. Figure 2 .
[0016] Legend: 1. Server cabinet; 2. Cabinet door; 3. Control panel; 4. Cooling mechanism; 401. Drive motor; 402. Lead screw; 403. First equipment rack; 404. Second equipment rack; 405. Third equipment rack; 406. Exhaust fan; 407. Temperature sensing module; 5. Base; 6. Lifting mechanism; 601. Fixed seat; 602. Base; 603. Self-locking caster wheel; 604. Hydraulic rod; 7. Slide rail; 8. Slider; 9. Insert block; 10. Limiting groove; 11. Limiting strip; 12. Receiving groove; 13. Spring assembly; 14. First ventilated mesh plate; 15. Second ventilated mesh plate. Detailed Implementation
[0017] To make the above-mentioned objects, features and advantages of the present invention more apparent and understandable, the specific embodiments of the present invention will be further described in detail below with reference to the accompanying drawings.
[0018] Secondly, the present invention is described in detail with reference to the schematic diagrams. When detailing the embodiments of the present invention, for ease of explanation, the cross-sectional views illustrating the device structure may be partially enlarged, not according to the usual scale. Furthermore, the schematic diagrams are merely examples and should not limit the scope of protection of the present invention. In addition, actual fabrication should include three-dimensional spatial dimensions of length, width, and depth.
[0019] Please see Figure 1-5 The present invention provides a cloud-based big data server cabinet for a computer, including a server cabinet 1, a cabinet door 2 connected to one side of the server cabinet 1 by a hinge, an operation panel 3 embedded and fixedly connected to the top of the cabinet door 2, and a cooling mechanism 4 provided inside the server cabinet 1.
[0020] The cooling mechanism 4 includes three drive motors 401 embedded and fixed inside the base 5. The drive shafts of the three drive motors 401 are all fixedly connected to lead screws 402. The outer walls of the three lead screws 402 are respectively threaded to a first equipment frame 403, a second equipment frame 404, and a third equipment frame 405. Exhaust fans 406 are embedded and fixedly connected inside the first equipment frame 403, the second equipment frame 404, and the third equipment frame 405. Temperature sensing modules 407 are fixedly connected to both sides of the exhaust fans 406.
[0021] The server cabinet 1 has slide rails 7 fixedly connected to both sides of its inner wall. The first equipment rack 403, the second equipment rack 404, and the third equipment rack 405 have sliders 8 fixedly connected to both sides, and the sliders 8 are slidably connected to the slide rails 7. Whenever any lead screw 402 rotates, the first equipment rack 403, the second equipment rack 404, and the third equipment rack 405 corresponding to that lead screw 402 can move and rise along the slide rails 7.
[0022] In this embodiment, the first device rack 403, the second device rack 404, and the third device rack 405 are evenly distributed inside the server cabinet 1. The first device rack 403, the second device rack 404, and the third device rack 405 are located in the upper, middle, and lower areas of the cabinet, respectively, and can cover the area where the server is located after being moved.
[0023] The temperature sensing module 407 includes a wireless signal transceiver module and three temperature sensing probes. The three temperature sensing probes are distributed at the middle height of the first equipment rack 403, the second equipment rack 404, and the third equipment rack 405. When the first equipment rack 403, the second equipment rack 404, and the third equipment rack 405 move, the corresponding temperature sensing probes can be moved. The multiple temperature sensing probes are evenly distributed on their respective equipment racks, which facilitates temperature monitoring of servers at the same height.
[0024] The bottom of the server cabinet 1 is fixedly connected to a base 5, and a lifting mechanism 6 is fixedly connected inside the base 5. The lifting mechanism 6 includes a fixed seat 601, with inserts 9 on both sides of the fixed seat 601. A base 602 is provided inside the fixed seat 601, and self-locking casters 603 are fixedly connected to the four corners of the base 602. A hydraulic rod 604 is fixedly connected to the top of the fixed seat 601.
[0025] Before use, connect the hydraulic rod 604 to the external oil pump. The hydraulic rod 604 can drive the base 602 to descend in the fixed seat 601, so that the self-locking caster 603 replaces the bottom surface of the base 5 to contact the ground. At this time, the server cabinet 1 can be moved without disassembling the PTZ big data server inside the cabinet before moving it, which not only saves manpower but also saves a lot of time.
[0026] In this embodiment, limiting grooves 10 are provided on both sides of the inner wall of the fixed base 601, and limiting strips 11 corresponding to the limiting grooves 10 are fixedly connected to both sides of the outer wall of the base 602. The limiting strips 11 are slidably connected to the inner wall of the limiting grooves 10. The limiting strips 11 can slide in the limiting grooves 10, which facilitates limiting the lifting position of the fixed base 601.
[0027] The outer wall of the fixing base 601 has receiving grooves 12 on both sides, and the receiving grooves 12 and the insert block 9 are fixedly connected by a spring assembly 13. The side wall of the base 5 has a through hole corresponding to the insert block 9. Through the elastic force of the spring assembly 13, the insert block 9 can be driven to pass through the through hole and extend outward, which facilitates the assembly of the fixing base 601.
[0028] The server cabinet 1 has a first ventilated mesh panel 14 bolted to the side away from the cabinet door 2, and the lifting mechanism 6 has a second ventilated mesh panel 15 on its top and side walls. The first ventilated mesh panel 14 and the second ventilated mesh panel 15 facilitate air circulation inside the cabinet and increase heat dissipation and cooling efficiency.
[0029] Working principle: In normal operating conditions, the drive motor 401, exhaust fan 406, and temperature sensing module 407 are connected to an external power supply. The three drive motors 401, each fixedly connected to the lead screw 402, can be started independently according to control commands.
[0030] In this embodiment, different drive motors 401 drive the lead screw 402 to rotate, thereby moving the corresponding equipment rack along the slide rail 7. Each equipment rack is equipped with an exhaust fan 406, and temperature sensing modules 407 on both sides can monitor the temperature of servers at the same height in real time. Multiple temperature sensing probes distributed on each equipment rack can monitor the server area at the same height in real time.
[0031] When an excessively high temperature is detected in a localized area within the cabinet, the control system issues a command to start motor 401, which in turn moves the corresponding equipment rack (e.g., the second equipment rack 404) to the overheated area and activates the exhaust fan 406 on that rack. This achieves precise, directional, forced air cooling of the hot spot, thereby efficiently and energy-savingly controlling the temperature. The movement range of the first equipment rack 403, the second equipment rack 404, and the third equipment rack 405 can cover the entire area of the cabinet.
[0032] Traditional data centers often require moving server racks due to layout adjustments, equipment maintenance, or upgrades. Currently, moving a fully loaded server rack is extremely inconvenient, typically requiring the servers to be disassembled first, then reinstalled after the rack is in place. This process not only consumes a lot of manpower and time, but the frequent plugging and unplugging also increases the risk of equipment damage and loose data interfaces.
[0033] In contrast, in this application, when the entire server rack needs to be moved, oil is first supplied to the hydraulic rod 604 of the lifting mechanism 6 via an external oil pump, driving the hydraulic rod 604 to extend and push the base 602 to descend smoothly within the fixed seat 601. During this process, the limiting strips 11 on both sides of the base 602 slide along the limiting grooves 10 on the inner wall of the fixed seat 601, ensuring stability and preventing tilting during the descent.
[0034] As the base 602 descends, the self-locking casters 603 at its four corners finally contact and support the ground. At this point, the entire weight of the server cabinet 1 is supported by the casters 603, and the bottom of the base 5 is lifted off the ground. Operators can then easily move the fully loaded server cabinet to a new location without disassembling internal equipment, greatly saving manpower and time. This reduces the risk of physical damage and connection failures that may occur during equipment handling. After moving into position, the hydraulic rod 604 is retracted, and the base 602, along with the casters 603, rises back to its original position, with the weight of the cabinet once again supported by the base 5.
[0035] Throughout the entire operation, the first ventilation mesh plate 14 on the back of the server cabinet 1 and the heat dissipation window on the cabinet door 2 corresponding to the first ventilation mesh plate 14, together with the second ventilation mesh plate 15 on the lifting mechanism 6, form an air circulation channel, which promotes the exchange of air inside and outside the cabinet, thereby improving the overall heat dissipation efficiency.
[0036] Although the present invention has been described above with reference to embodiments, various modifications can be made and components can be replaced with equivalents without departing from the scope of the invention. In particular, as long as there is no structural conflict, the features in the disclosed embodiments can be combined with each other in any manner. The lack of an exhaustive description of these combinations in this specification is merely for the sake of brevity and resource conservation. Therefore, the present invention is not limited to the specific embodiments disclosed herein, but includes all technical solutions falling within the scope of the claims.
Claims
1. A PTZ big data server cabinet for computers, comprising a server cabinet (1), characterized in that, The server cabinet (1) has a door (2) connected to one side by a hinge. An operation panel (3) is embedded and fixedly connected to the top of the door (2). A cooling mechanism (4) is provided inside the server cabinet (1). A base (5) is fixedly connected to the bottom of the server cabinet (1). A lifting mechanism (6) is fixedly connected inside the base (5). The cooling mechanism (4) includes three drive motors (401) embedded and fixed inside the base (5). The drive shafts of the three drive motors (401) are all fixedly connected to lead screws (402). The outer walls of the three lead screws (402) are respectively threaded to a first equipment frame (403), a second equipment frame (404), and a third equipment frame (405). Exhaust fans (406) are embedded and fixedly connected inside the first equipment frame (403), the second equipment frame (404), and the third equipment frame (405). Temperature sensing modules (407) are fixedly connected to both sides of the exhaust fans (406).
2. The PTZ big data server cabinet for a computer according to claim 1, characterized in that, The lifting mechanism (6) includes a fixed seat (601), with inserts (9) on both sides of the fixed seat (601), a base (602) inside the fixed seat (601), self-locking casters (603) fixedly connected to the four corners of the base (602), and a hydraulic rod (604) fixedly connected to the top inside the fixed seat (601).
3. A PTZ big data server cabinet for a computer according to claim 1, characterized in that, The server cabinet (1) has slide rails (7) fixedly connected to both sides of its inner wall. The first equipment rack (403), the second equipment rack (404) and the third equipment rack (405) have sliders (8) fixedly connected to both sides. The sliders (8) are slidably connected to the slide rails (7).
4. A PTZ big data server cabinet for a computer according to claim 1, characterized in that, The first equipment rack (403), the second equipment rack (404) and the third equipment rack (405) are evenly distributed inside the server cabinet (1).
5. A PTZ big data server cabinet for a computer according to claim 2, characterized in that, The fixed base (601) has limit grooves (10) on both sides of its inner wall, and the base (602) has limit strips (11) corresponding to the limit grooves (10) fixedly connected to both sides of its outer wall. The limit strips (11) are slidably connected to the inner wall of the limit grooves (10).
6. A PTZ big data server cabinet for a computer according to claim 2, characterized in that, The outer walls of the fixed base (601) are provided with receiving grooves (12), and the receiving grooves (12) and the insert block (9) are fixedly connected with a spring assembly (13).
7. A PTZ big data server cabinet for a computer according to claim 1, characterized in that, The server cabinet (1) is fixedly connected to a first breathable mesh plate (14) by bolts on the side away from the cabinet door (2), and the lifting mechanism (6) is provided with a second breathable mesh plate (15) on the top and side wall.
8. A PTZ big data server cabinet for a computer according to claim 1, characterized in that, The temperature sensing module (407) includes a wireless signal transceiver module and three temperature sensing probes, which are distributed at the middle height of the first equipment rack (403), the second equipment rack (404) and the third equipment rack (405).