A new energy station power prediction modular cabinet
By introducing transfer and drive components into the modular cabinet for power prediction in new energy power plants, the problems of inconvenient cabinet maintenance and safety hazards have been solved, enabling stable cabinet movement and automated unlocking, thus improving maintenance efficiency and safety.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BEIJING QIHENG TECHNOLOGY CO LTD
- Filing Date
- 2025-06-30
- Publication Date
- 2026-07-14
AI Technical Summary
The existing modular cabinets for power prediction in new energy power plants are inconvenient to maintain and operate, and pose safety hazards. They lack convenient cabinet movement mechanisms and automated locking and releasing mechanisms, resulting in low maintenance efficiency and increased safety risks.
A modular cabinet for power prediction in new energy power plants was designed, including a transfer component and a drive component. The transfer component includes a limit rod, lifting block, limit frame, slide rail, mounting plate, transfer frame, locking buckle, etc. The cabinet can be automatically unlocked and locked by electric rod and drive slot. Combined with the linkage between tilting and pressing block and drive block, the cabinet can be stably moved and its height can be adjusted.
It enables safe and stable movement of the cabinet, avoids cable swaying and falling off, improves maintenance comfort and efficiency, reduces operator fatigue and safety risks, simplifies locking and unlocking steps, and enhances the convenience and security of the overall maintenance process.
Smart Images

Figure CN224502680U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of cabinet technology, specifically relating to a modular cabinet for power prediction in new energy power plants. Background Technology
[0002] In the operation and management of new energy power plants (such as wind farms and photovoltaic power plants), the power prediction system is a key component in ensuring stable grid operation and optimizing power generation efficiency. This system is typically deployed in a dedicated prediction cabinet, containing multiple modular cabinets to house core hardware such as data acquisition cards, communication equipment, and computing servers. These modular cabinets require regular maintenance, inspection, upgrades, or component replacement (such as hot-swapping of data acquisition cards).
[0003] However, existing predictive cabinets and their modular cabinet deployment methods generally have the following significant drawbacks, causing numerous inconveniences and risks to daily operation and maintenance:
[0004] Maintenance and operation are inconvenient and pose safety hazards:
[0005] Fixed height presents operational difficulties: Traditional server racks are typically installed at a fixed height within the cabinet. When operations are required on racks located at higher or lower positions (especially for components requiring hot-swapping), maintenance personnel often need to use ladders to climb or spend extended periods bending or squatting. This not only significantly reduces maintenance efficiency and increases operator fatigue but also introduces safety risks such as slips, falls, or muscle strain.
[0006] Lack of convenient rack relocation mechanisms: Existing designs typically lack effective and safe rack relocation assistance devices. When the entire rack needs to be pulled out of the cabinet for more comprehensive maintenance, the operation is laborious and prone to causing the rack to tip over or damage the equipment due to improper force, while also increasing the possibility of injury to the operator.
[0007] The locking / unlocking mechanism is cumbersome and inefficient.
[0008] Manual operation of latches is inefficient: Locking latches commonly used in fixed server racks typically require maintenance personnel to manually unlock and relock each one individually. This process is time-consuming and labor-intensive, especially when operating multiple latches within a confined space, which is extremely inconvenient.
[0009] Lack of a linked release mechanism: Existing technologies typically lack an automated locking and release mechanism that can be linked to rack movement. This makes unlocking a separate and cumbersome step before moving the rack, reducing the efficiency of the overall maintenance process. Utility Model Content
[0010] The purpose of this utility model is to provide a modular cabinet for power prediction in new energy power plants, which aims to solve the problems mentioned in the background art.
[0011] A modular cabinet for power prediction in new energy power plants, comprising:
[0012] Cabinet;
[0013] A transfer assembly, located on the inner wall of the cabinet, comprises: a limit rod, a lifting block, a limit frame, a slide rail, a mounting plate, a transfer frame, a mounting bracket, a locking buckle, a drive block, a support spring, a moving plate, a clamping buckle, a cabinet, a slot, a pressing block, and a drive assembly. The limit rod is embedded in both sides of the inner wall of the cabinet. The lifting block is slidably sleeved on the outer wall of the limit rod. The limit frame is rotatably inserted into the opening on the outer wall of the lifting block. The slide rail is embedded in both sides of the inner wall of the cabinet. The mounting plate is fixedly sleeved on the outer wall of the slide rail by bolts. The transfer frame is slidably embedded in the top of the outer wall of the limit frame. The mounting bracket is fixedly installed on both sides of the top outer wall of the mounting plate. The locking buckle is slidably embedded in the inner wall of the mounting bracket. The support spring is sleeved on the outer wall of the locking buckle. The clamping buckle is fixedly installed on the outer walls of both ends of the moving plate. The clamping buckle is slidably embedded in the outer wall of the transfer frame. The cabinet is located at the center of the top of the outer wall of the mounting plate. The slot is opened at the openings on both sides of the outer wall of the cabinet. The slot matches the locking buckle. The pressing block is fixedly installed on both sides of the outer wall of the transfer frame. The pressing block matches the driving block. The driving assembly is located on the outer wall of the transfer frame.
[0014] Furthermore, the drive assembly includes an electric rod, a drive rod, and a drive slot.
[0015] Furthermore, the drive rod is fixedly mounted on the outer wall of the output end of the electric rod, and the drive groove is opened on the outer wall of the moving plate.
[0016] Furthermore, the drive rod is slidably embedded in the inner wall of the drive groove.
[0017] Furthermore, the outer walls of both the extrusion block and the drive block are inclined, and the cross-section of the drive groove is inclined.
[0018] Furthermore, a cabinet door is hinged to one side of the outer wall of the cabinet.
[0019] Compared with the prior art, the beneficial effects of this utility model are:
[0020] When internal cabinets need to be inspected or maintained, the transfer assembly allows operators to easily and smoothly move the target cabinet from its working position. The specially designed rear opening of the cabinet, combined with the transfer motion, allows network cables, power cables, and other cables connected to the cabinet to be orderly guided and stably dragged via a cable management system. This effectively avoids the risk of cables shaking, tangling, or accidentally falling off during movement, greatly ensuring the safety and stability of the equipment movement and preventing equipment damage or connection interruptions caused by cable pulling. It simplifies maintenance operations and improves comfort and efficiency. For operations requiring contact with the cabinet interior, such as hot-swapping of data acquisition cards, the transfer assembly provides a crucial height adjustment function. Operators can adjust the height using the lifting blocks to easily reach the optimal ergonomic operating position for the target cabinet. This function completely eliminates the inconvenience and hassle of maintenance personnel frequently climbing ladders or bending over for extended periods, significantly improving maintenance comfort, reducing operator fatigue and potential safety risks, and also increasing maintenance efficiency. The transfer process integrates a highly efficient linkage locking mechanism. When the transfer rack approaches the target rack, its tilting clamping block first contacts and pushes the drive block, overcoming the spring force of the support spring and automatically disengaging the locking latches from the rack's slots for quick unlocking. This design eliminates the need for manual unlocking. After all locking latches are fully released, the electric lever activates, precisely controlling the movement of the moving plate and its clamping latches to engage with the rack's slots, ensuring reliable rack gripping. The reverse operation allows for rack return and locking. The entire process is seamless, simple, precise, and reliable. Attached Figure Description
[0021] The accompanying drawings are provided to further illustrate the present invention and form part of the specification. They are used together with the embodiments of the present invention to explain the present invention, but do not constitute a limitation thereof. In the drawings:
[0022] Figure 1 This is a perspective view of the present utility model;
[0023] Figure 2 This is a perspective view of the lifting block of this utility model;
[0024] Figure 3 This is a perspective view of the transfer frame of this utility model;
[0025] Figure 4 This is a perspective view of the extrusion block of this utility model;
[0026] Figure 5 This is an enlarged schematic diagram of A of this utility model;
[0027] Figure 6 This is an enlarged schematic diagram of utility model B.
[0028] In the diagram: 1. Cabinet; 2. Limiting rod; 3. Lifting block; 4. Limiting frame; 5. Slide rail; 6. Mounting plate; 7. Transfer frame; 8. Mounting frame; 9. Locking buckle; 10. Drive block; 11. Support spring; 12. Electric rod; 13. Drive rod; 14. Moving plate; 15. Drive slot; 16. Clamping buckle; 101. Cabinet door; 601. Cabinet; 701. Extrusion block; 6011. Slot. Detailed Implementation
[0029] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0030] In the description of this utility model, it should be noted that the terms "upper," "lower," "inner," "outer," "top / bottom," etc., indicating the orientation or positional relationship are based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model. Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance.
[0031] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installed," "equipped with," "sleeved / connected," "connected," etc., should be interpreted broadly. For example, "connection" can be a fixed connection, a detachable connection, or an integral connection; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium; it can be a connection within two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.
[0032] Please see Figure 1-6 The technical solution provided in this embodiment is as follows:
[0033] A modular cabinet for power prediction in new energy power plants, comprising:
[0034] Cabinet 1;
[0035] The transfer assembly, located on the inner wall of cabinet 1, includes: a limit rod 2, a lifting block 3, a limit frame 4, a slide rail 5, a mounting plate 6, a transfer frame 7, a mounting bracket 8, a locking buckle 9, a drive block 10, a support spring 11, a moving plate 14, a clamping buckle 16, a cabinet 601, a slot 6011, a pressing block 701, and a drive assembly. The limit rod 2 is embedded on both sides of the inner wall of cabinet 1. The lifting block 3 is slidably sleeved on the outer wall of the limit rod 2. The limit frame 4 is rotatably inserted into the opening on the outer wall of the lifting block 3. The slide rail 5 is embedded on both sides of the inner wall of cabinet 1. The mounting plate 6 is fixedly sleeved on the outer wall of the slide rail 5 by bolts. The transfer frame 7 is slidably embedded on the outer wall of the limit frame 4. At the top of the wall, the mounting bracket 8 is fixedly set on both sides of the top of the outer wall of the mounting plate 6. The locking buckle 9 is slidably embedded in the inner wall of the mounting bracket 8. The support spring 11 is sleeved on the outer wall of the locking buckle 9. The clamping buckle 16 is fixedly set on the outer walls of both ends of the moving plate 14. The clamping buckle 16 is slidably embedded in the outer wall of the transfer frame 7. The cabinet 601 is set at the center of the top of the outer wall of the mounting plate 6. The slot 6011 is opened at the openings on both sides of the outer wall of the cabinet 601. The slot 6011 matches the locking buckle 9. The pressing block 701 is fixedly set on both sides of the outer wall of the transfer frame 7. The pressing block 701 matches the driving block 10. The driving assembly is set on the outer wall of the transfer frame 7.
[0036] In a specific embodiment of this utility model, the transfer component first deploys the cabinet 1 to the designated working position. An opening is made at the rear of the cabinet 1 to facilitate the entry of the cable management device and to facilitate heat dissipation. During inspection and maintenance of the mobile cabinet 601, the cable management device allows network cables and power cords to be stably dragged without shaking or falling, ensuring the safety and stability of the mobile cabinet 601. When the data acquisition card of the cabinet 601 needs hot-swapping or maintenance, the lifting block 3 is moved to move on the limit rod 2. Then, the lifting block 3 drives the limit frame 4 to move, making the limit frame 4 flush with the plane of the mounting plate 6 where the corresponding cabinet 601 is located. Then, the component is pulled... The transfer frame 7 causes the pressing block 701 to first contact the drive block 10. Under the pressure, the locking buckle 9 overcomes the action of the support spring 11, causing the locking buckle 9 to disengage from the slot 6011 and release the latch on the cabinet 601. Then, after all four locking buckles 9 are disengaged, the electric rod 12 is activated, causing the drive rod 13 to move inside the drive slot 15, causing the moving plate 14 to drive the clamping buckle 16 to lock the slot 6011. At this time, the transfer frame 7 is pulled, causing the entire cabinet 601 to be pulled onto the limit frame 4, further adjusting the height of the limit frame 4 to facilitate hot-swapping and maintenance by the staff, avoiding the need for staff to stand at the same height or squat down to operate, and improving the comfort of maintenance.
[0037] Specifically, the drive assembly includes an electric rod 12, a drive rod 13, and a drive slot 15.
[0038] In a specific embodiment of this utility model, the driving component can ensure stable and high-precision transmission of driving force.
[0039] Specifically, the drive rod 13 is fixedly installed on the outer wall of the output end of the electric rod 12, and the drive groove 15 is opened on the outer wall of the moving plate 14.
[0040] In a specific embodiment of this utility model, the drive groove 15 is opened on the outer wall of the moving plate 14, which can ensure the operation accuracy.
[0041] Specifically, the drive rod 13 is slidably embedded in the inner wall of the drive groove 15.
[0042] In a specific embodiment of this utility model, the drive rod 13 is slidably embedded in the inner wall of the drive groove 15, which can ensure the stable transmission of torque.
[0043] Specifically, the outer walls of both the extrusion block 701 and the drive block 10 are inclined, and the cross-section of the drive groove 15 is inclined.
[0044] In a specific embodiment of this utility model, the cross-section of the drive groove 15 is inclined, which facilitates the movement of the clamping buckle 16.
[0045] Specifically, a cabinet door 101 is hinged to one side of the outer wall of cabinet 1.
[0046] In a specific embodiment of this utility model, the cabinet door 101 can ensure the cleanliness of the inside of the cabinet 1.
[0047] Working principle:
[0048] The transfer assembly first deploys cabinet 1 to the designated working position. An opening is made at the rear of cabinet 1 to facilitate the entry of the cable management device and to facilitate heat dissipation. During inspection and maintenance of the mobile cabinet 601, the cable management device allows network cables and power cords to be stably dragged without shaking or falling, ensuring the safety and stability of the mobile cabinet 601. When the data acquisition card of cabinet 601 needs hot-swapping or maintenance, the lifting block 3 is moved to the limit rod 2. Then, the lifting block 3 drives the limit frame 4 to move, making the limit frame 4 flush with the mounting plate 6 where the corresponding cabinet 601 is located. Finally, the transfer frame 7 is pulled, so that... The pressing block 701 first contacts the driving block 10. Under the pressure, the locking buckle 9 overcomes the action of the supporting spring 11, causing the locking buckle 9 to disengage from the slot 6011 and release the latch on the cabinet 601. Then, after all four locking buckles 9 are disengaged, the electric rod 12 is activated, causing the driving rod 13 to move inside the driving slot 15. This causes the moving plate 14 to drive the clamping buckle 16 to lock the slot 6011. At this time, the transfer frame 7 is pulled, causing the entire cabinet 601 to be pulled onto the limiting frame 4. The height of the limiting frame 4 is further adjusted to facilitate hot-swapping and maintenance by the staff, avoiding the need for staff to stand at the same height or squat down to operate, thus improving the comfort of maintenance.
[0049] Finally, it should be noted that the above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.
Claims
1. A modular cabinet for power prediction in new energy power plants, characterized in that, include, Cabinet (1); A transfer assembly is located on the inner wall of the cabinet (1), wherein: the transfer assembly includes a limiting rod (2), a lifting block (3), a limiting frame (4), a slide rail (5), a mounting plate (6), a transfer frame (7), a mounting frame (8), a locking buckle (9), a drive block (10), a support spring (11), a moving plate (14), a clamping buckle (16), a cabinet (601), a slot (6011), a pressing block (701), and a drive assembly. The limiting rod (2) is embedded on both sides of the inner wall of the cabinet (1). The lifting block (3) is slidably sleeved on the outer wall of the limiting rod (2). The limiting frame (4) is rotatably inserted into the opening on the outer wall of the lifting block (3). The slide rail (5) is embedded on both sides of the inner wall of the cabinet (1). The mounting plate (6) is fixedly sleeved on the outer wall of the slide rail (5) by bolts. The transfer frame (7) is slidably embedded on the limiting frame (4). At the top of the outer wall of the mounting plate (6), the mounting bracket (8) is fixedly set on both sides of the top of the outer wall of the mounting plate (6), the locking buckle (9) is slidably embedded in the inner wall of the mounting bracket (8), the support spring (11) is sleeved on the outer wall of the locking buckle (9), the clamping buckle (16) is fixedly set on the outer walls of both ends of the moving plate (14), the clamping buckle (16) is slidably embedded in the outer wall of the transfer frame (7), the cabinet (601) is set at the center of the top of the outer wall of the mounting plate (6), the slot (6011) is opened at the openings on both sides of the outer wall of the cabinet (601), the slot (6011) matches the locking buckle (9), the pressing block (701) is fixedly set on both sides of the outer wall of the transfer frame (7), the pressing block (701) matches the driving block (10), and the driving assembly is set on the outer wall of the transfer frame (7).
2. The modular cabinet for power prediction in a new energy power station according to claim 1, characterized in that, The drive assembly includes an electric rod (12), a drive rod (13), and a drive groove (15).
3. A modular cabinet for power prediction in a new energy power station according to claim 2, characterized in that, The drive rod (13) is fixedly installed on the outer wall of the output end of the electric rod (12), and the drive groove (15) is opened on the outer wall of the moving plate (14).
4. A modular cabinet for power prediction in a new energy power station according to claim 3, characterized in that, The drive rod (13) is slidably embedded in the inner wall of the drive groove (15).
5. A modular cabinet for power prediction in a new energy power station according to claim 4, characterized in that, The outer walls of the extrusion block (701) and the drive block (10) are both inclined, and the cross-section of the drive groove (15) is inclined.
6. A modular cabinet for power prediction in a new energy power station according to claim 5, characterized in that, A cabinet door (101) is hinged to one side of the outer wall of the cabinet (1).