A multi-cavity distributed storage platform
By designing anti-detachment and displacement mechanisms in a multi-cavity distributed storage platform, the problem of insufficient modularity in traditional storage devices is solved, enabling efficient memory expansion and automatic switching, and improving storage space utilization and data interaction efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- V & G INFORMATION SYSTEM CO LTD
- Filing Date
- 2025-05-16
- Publication Date
- 2026-06-30
Smart Images

Figure CN224437176U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of storage, specifically to a multi-cavity distributed storage platform. Background Technology
[0002] Distributed storage involves distributing data across multiple devices, each with its own storage space and data processing capabilities, forming a distributed system. This system can utilize multiple storage servers to share the storage load, improving system reliability, availability, and access efficiency.
[0003] Traditional distributed storage devices use independent memory stacking, and the cavity lacks modular design, making it difficult to achieve high-density arrangement and dynamic expansion of memory. This results in low space utilization and high expansion and maintenance costs. Furthermore, the lack of an automatic switching disk read mechanism during data access and writing between memory modules leads to data interaction delays and affects response speed. Utility Model Content
[0004] (a) Purpose of the utility model
[0005] To address the technical problems existing in the background art, this utility model proposes a multi-cavity distributed storage platform, which features convenient expansion of multi-cavity distributed installed memory and automatic switching and reading of each memory.
[0006] (II) Technical Solution
[0007] To solve the above-mentioned technical problems, this utility model provides a multi-cavity distributed storage platform, including a storage platform and a storage mechanism including a plurality of distributed storage boxes installed in the inner cavity of the storage platform;
[0008] The front end of the distributed storage box is used to insert the memory, and the notch at the rear corresponds to the memory interface at the end of the memory.
[0009] The anti-detachment mechanism includes a shaft disposed at the open end of the distribution storage box, an anti-detachment plate sleeved on the outside of the shaft, and a protruding magnetic fastener formed on the end face of the anti-detachment plate facing the distribution storage box;
[0010] The first displacement mechanism includes a first rod frame symmetrically arranged inside the storage platform, a first screw is provided in the middle of the first rod frame, and first guide rods are provided on both sides of the first screw. The first screw is controlled to rotate by the drive of a first motor, and a first lead screw slide is sleeved on the outside and slides along the first guide rod.
[0011] The second displacement mechanism includes a second rod frame mounted on the first lead screw slide, a second screw is provided in the middle of the second rod frame, and second guide rods are provided on both sides of the second screw. The second screw is controlled to rotate by a drive device, and a second lead screw slide that moves along the second guide rod is sleeved on its outside.
[0012] The disk reading mechanism includes a cylinder mounted on the second lead screw slide, a movable piston rod installed at the output end of the cylinder, and a disk reading end seat connected to the other end of the piston rod. The disk reading end seat has a disk reading interface formed on it to cooperate with the memory interface.
[0013] Preferably, the distributed storage boxes are arranged horizontally and vertically within the storage platform, and the internal cavities are for the distributed installation of the memory.
[0014] Preferably, corner pads are installed at the internal corners of the distributed storage box, and ventilation slots are provided at both ends.
[0015] Preferably, the anti-detachment plate rotates along the axis of the shaft, and the magnetic fastener on the anti-detachment plate engages with a notch on the distribution storage box.
[0016] Preferably, the first lead screw slide undergoes linear displacement in the lateral direction, and the second lead screw slide undergoes linear displacement in the longitudinal direction.
[0017] Preferably, the disk reader connector is connected to any memory via the disk reader interface and the memory interface, and the other end is connected to an external device via a bendable cable.
[0018] The above-mentioned technical solution of this utility model has the following beneficial technical effects: the memory is distributed and installed in the various distributed storage cavities of the storage platform. Each memory is relatively independent and has its own storage space and data processing capability, forming a distributed system. When writing and retrieving stored content, it is achieved through the first displacement mechanism, the second displacement mechanism and the disk reading mechanism. After the disk reading structure moves to the corresponding memory position according to the working requirements, the disk reading interface of the disk reading terminal is connected to the memory interface to perform distributed memory writing or retrieval. During access and retrieval, each memory is relatively independent and the contents stored in different memories do not interfere with each other. Attached Figure Description
[0019] Figure 1 This is a schematic diagram of the structure of this utility model;
[0020] Figure 2 This is a schematic diagram of the internal structure of the present invention;
[0021] Figure 3 This is a schematic diagram of the cooperative structure of the first displacement mechanism and the second displacement mechanism of this utility model;
[0022] Figure 4 This is a schematic diagram of the anti-detachment mechanism of this utility model.
[0023] Figure label:
[0024] 1. Storage platform; 21. Distributed storage box; 22. Corner pad; 23. Ventilation slot; 3. Memory; 4. Memory interface; 51. Shaft; 52. Anti-detachment plate; 53. Magnetic fastener; 61. First rod frame; 62. First screw; 63. First guide rod; 64. First motor; 65. First lead screw slide; 71. Second rod frame; 72. Second screw; 73. Second guide rod; 74. Second lead screw slide; 81. Cylinder; 82. Piston rod; 83. Disk reading end seat; 84. Disk reading interface. Detailed Implementation
[0025] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to specific embodiments and accompanying drawings. It should be understood that these descriptions are merely exemplary and not intended to limit the scope of this utility model. Furthermore, descriptions of well-known structures and technologies are omitted in the following description to avoid unnecessarily obscuring the concept of this utility model.
[0026] like Figure 1-4 As shown, the present invention proposes a multi-cavity distributed storage platform, including a storage platform 1, and a storage mechanism including a plurality of distributed storage boxes 21 installed in the cavity of the storage platform 1.
[0027] The front end of the distributed storage box 21 is used to penetrate the memory 3, and the notch at the rear corresponds to the memory interface 4 at the end of the memory 3.
[0028] The anti-detachment mechanism includes a shaft 51 disposed at the opening end of the distribution storage box 21, an anti-detachment plate 52 sleeved on the outside of the shaft 51, and a protruding magnetic fastener 53 formed on the end face of the anti-detachment plate 52 facing the distribution storage box 21.
[0029] The first displacement mechanism includes a first rod 61 symmetrically arranged inside the storage platform 1, a first screw 62 arranged in the middle of the first rod 61, a first guide rod 63 arranged on both sides of the first screw 62, the first screw 62 is controlled to rotate by the drive of the first motor 64, and a first lead screw slide 65 that slides along the first guide rod 63 is sleeved on the outside.
[0030] The second displacement mechanism includes a second rod frame 71 mounted on the first lead screw slide 65, a second screw 72 provided in the middle of the second rod frame 71, second guide rods 73 provided on both sides of the second screw 72, the second screw 72 being controlled to rotate by the drive device, and a second lead screw slide 74 that moves along the second guide rods 73 is sleeved on the outside.
[0031] The disk reading mechanism includes a cylinder 81 mounted on the second lead screw slide 74. A movable piston rod 82 is mounted on the output end of the cylinder 81. The other end of the piston rod 82 is connected to a disk reading end seat 83. A disk reading interface 84 that mates with the memory interface 4 is formed on the disk reading end seat 83.
[0032] It should be noted that the distributed storage boxes 21 are arranged horizontally and vertically within the storage platform 1, and the internal cavities are used for the distributed installation of the memory 3. In this application, three are arranged horizontally and vertically to form a distributed storage platform.
[0033] It should be added that the disk reader 83 connects to any memory 3 through the cooperation of the disk reader interface 84 and the memory interface 4, and the other end is connected to an external device through a flexible cable to establish communication with the external device for data storage or retrieval.
[0034] In this embodiment, nine horizontally and vertically stacked distributed storage boxes 21 are provided in the storage platform 1. The memory 3 is distributed and installed in the cavity of each distributed storage box 21. Each memory 3 is relatively independent and has its own storage space and data processing capability, forming a distributed system.
[0035] When writing and retrieving stored content, it is achieved through a first displacement mechanism, a second displacement mechanism, and a disk reading mechanism. The first motor 64 drives the first screw 62 to rotate, and the first lead screw slide 65 slides along the first guide rod 63 under threaded engagement, making linear displacement in the lateral direction to adjust the lateral position of the disk reading mechanism.
[0036] The second lead screw slide 74 works in the same way, and can make linear displacement along the longitudinal direction to adjust the position of the reading mechanism in the longitudinal direction.
[0037] After the reading structure moves to the corresponding memory 3 position according to the work requirements, the cylinder 81 drives the piston rod 82 to extend, driving the reading interface 84 of the reading end seat 83 to connect with the memory interface 4, so as to write or call the distributed memory 3.
[0038] When in use, the storage platform 1 expands the storage capacity through the distributed storage of the memory 3, and each memory 3 is relatively independent when accessing and calling, and the contents stored in different memory 3 do not interfere with each other.
[0039] It is understandable that corner pads 22 are installed at the internal corners of the distributed storage box 21. The corner pads 22 are used for shock-resistant support of the memory 3 and improve the shock resistance of the memory 3 installation; and ventilation slots 23 are provided at both ends.
[0040] like Figure 4As shown, the anti-detachment plate 52 rotates along the axis of the shaft 51. After the memory 3 is installed in the distribution storage box 21, the anti-detachment plate 52 rotates inward along the axis of the shaft 51 until it adheres to the outer wall of the memory 3, thus limiting its installation position. At this time, the magnetic fastener 53 on the anti-detachment plate 52 cooperates with the notch opened on the distribution storage box 21, and the two are magnetically attached to each other, thus fixing and limiting the assembly point, effectively solving the problem of the memory 3 loosening and detaching from the distribution storage box 21.
[0041] It should be understood that the specific embodiments described above are merely illustrative or explanatory of the principles of this utility model and do not constitute a limitation thereof. Therefore, any modifications, equivalent substitutions, improvements, etc., made without departing from the spirit and scope of this utility model should be included within its protection scope. Furthermore, the appended claims are intended to cover all variations and modifications falling within the scope and boundaries of the appended claims, or equivalent forms of such scope and boundaries.
Claims
1. A multi-cavity distributed storage platform, characterized in that, It includes a storage platform (1), and the storage mechanism includes a plurality of distributed storage boxes (21) installed in the cavity of the storage platform (1); The front end of the distributed storage box (21) is used to insert the memory (3), and the notch at the rear corresponds to the memory interface (4) at the end of the memory (3). The anti-detachment mechanism includes a shaft (51) disposed at the opening end of the distribution storage box (21), an anti-detachment plate (52) is sleeved on the outside of the shaft (51), and a protruding magnetic fastener (53) is formed on the end face of the anti-detachment plate (52) facing the distribution storage box (21). The first displacement mechanism includes a first rod frame (61) symmetrically arranged inside the storage platform (1), a first screw (62) is arranged in the middle of the first rod frame (61), a first guide rod (63) is arranged on both sides of the first screw (62), the first screw (62) is controlled to rotate by the drive of the first motor (64), and a first lead screw slide (65) is sleeved on the outside and slides along the first guide rod (63); The second displacement mechanism includes a second rod frame (71) mounted on the first lead screw slide (65), a second screw (72) is provided in the middle of the second rod frame (71), and second guide rods (73) are provided on both sides of the second screw (72). The second screw (72) is controlled to rotate by the drive device, and a second lead screw slide (74) that moves along the second guide rod (73) is sleeved on the outside. The disk reading mechanism includes a cylinder (81) mounted on the second lead screw slide (74), a movable piston rod (82) is mounted on the output end of the cylinder (81), and the other end of the piston rod (82) is connected to a disk reading end seat (83), and a disk reading interface (84) is formed on the disk reading end seat (83) to cooperate with the memory interface (4).
2. The multi-cavity distributed storage platform according to claim 1, characterized in that, The distributed storage box (21) is arranged horizontally and vertically within the storage platform (1), and the internal cavity is for the distributed installation of the memory (3).
3. The multi-cavity distributed storage platform according to claim 1, characterized in that, The internal corner of the distributed storage box (21) is equipped with corner pads (22), and ventilation slots (23) are provided at both ends.
4. The multi-cavity distributed storage platform according to claim 1, characterized in that, The anti-detachment plate (52) rotates along the axis of the shaft (51), and the magnetic fastener (53) on the anti-detachment plate (52) cooperates with the notch opened on the distribution storage box (21).
5. A multi-cavity distributed storage platform according to claim 1, characterized in that, The first lead screw slide (65) makes a linear displacement in the transverse direction, and the second lead screw slide (74) makes a linear displacement in the longitudinal direction.
6. The multi-cavity distributed storage platform according to claim 1, characterized in that, The disk reader (83) is connected to any memory (3) through the disk reader interface (84) and the memory interface (4), and the other end is connected to an external device through a bendable cable.