A spliced packaging structure for server transportation
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HEYUAN HOUWEI PACKAGING CO LTD
- Filing Date
- 2025-07-03
- Publication Date
- 2026-06-09
Smart Images

Figure CN224336208U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of server packaging technology, and in particular to a splicing packaging structure for server transportation. Background Technology
[0002] In the digital information age, servers, as core devices for data storage, processing, and transmission, are of paramount importance for safe transportation. Because servers integrate numerous sophisticated electronic components, they must withstand various external forces during transport, including vibration, collisions, and stacking pressure.
[0003] However, the traditional splicing packaging structure for server transportation relies on simple connection methods such as tape and buckles to fix the box and cover, lacking effective limiting and support structures. As a result, the box and cover are prone to relative displacement during transportation, which cannot form a stable overall structure and weakens the packaging's ability to resist external impacts.
[0004] For example, during the transportation of servers, server boxes using traditional packaging may experience dents in some areas after multiple transfers and stackings due to vertical displacement of the box and cover during transport, causing collisions between the internal servers and the inner walls of the packaging. Utility Model Content
[0005] This utility model discloses a modular packaging structure for server transportation, aiming to solve the technical problem that traditional modular packaging structures for server transportation rely on simple connection methods such as tape and buckles to fix the box and cover, lacking effective limiting and support structures. As a result, the box and cover are prone to relative displacement during transportation, failing to form a stable overall structure and weakening the packaging's ability to resist external impacts.
[0006] To achieve the above objectives, the present invention adopts the following technical solution:
[0007] A modular packaging structure for server transportation includes a box body with two top cover plates connected to the top outer wall of the box body. The box body has multiple gripping holes on both sides of its outer wall. The structure also includes: a fixing mechanism comprising a base plate installed on the bottom outer wall of the box body; four second fixing posts evenly distributed on the outer wall of the base plate; limit blocks attached to the outer walls of the two second fixing posts; six first fixing posts evenly distributed on the top outer wall of the base plate; six connecting grooves on the outer wall of the box body; and four connecting grooves on the outer wall of the top cover plates. A vibration damping mechanism is located inside the box body.
[0008] In this solution, the base plate is installed on the outer wall of the bottom of the box, thereby providing an installation position for the upper components and preventing deformation of the bottom of the box. At this time, four second fixing posts and six first fixing posts are installed at equal intervals on the outer wall of the base plate. The first and second fixing posts and the outer wall of the box and the top cover are attached together, thereby limiting the relative displacement of the box and the top cover in the vertical direction and enhancing the overall height stability of the packaging. At the same time, the limiting blocks attached to the outer walls on both sides of the second fixing posts can further fix the position of the second fixing posts and help enhance the lateral pressure resistance of the fixing mechanism.
[0009] In a preferred embodiment, the vibration damping mechanism includes multiple rubber pads installed inside the housing, multiple telescopic rods connected to the bottom outer wall of the rubber pads, springs sleeved on the outer wall of the telescopic rods, multiple slots provided inside the housing, and the telescopic rods and springs are all installed inside the housing.
[0010] In this solution, a rubber pad is installed on the inner wall of the slot, and the rubber pad directly contacts the server's mounting feet. At this time, multiple telescopic rods and springs are installed on the bottom outer wall of the rubber pad. The elastic deformation of the springs and the elastic force of the rubber pad itself buffer external impact forces. At the same time, the telescopic rods provide support for the rubber pad, ensuring that the rubber pad can stably return to its original position after being subjected to force. Through the coordinated work of these three components, the damage to the server caused by vibration and impact during transportation is effectively reduced.
[0011] As described above, a modular packaging structure for server transportation includes a box body. The top outer wall of the box body is connected to two upper cover plates. The two outer walls of the box body have multiple gripping holes. The structure also includes: a fixing mechanism: the fixing mechanism includes a base plate installed on the bottom outer wall of the box body. Four second fixing posts are evenly distributed on the outer wall of the base plate. Limiting blocks are attached to the outer walls of the two sides of the second fixing posts. Six first fixing posts are evenly distributed on the top outer wall of the base plate. The outer wall of the box body has six connecting grooves, and the outer wall of the upper cover plate has four of the connecting grooves. A vibration damping mechanism: the vibration damping mechanism is located inside the box body. The modular packaging structure for server transportation provided by this utility model has the technical effect of improving the pressure resistance of the packaging box and improving the vibration resistance of the server during transportation. Attached Figure Description
[0012] Figure 1 This is a schematic diagram of the overall structure of a splicing packaging structure for server transportation proposed in this utility model.
[0013] Figure 2 This is a top view of the overall structure of a splicing packaging structure for server transportation proposed in this utility model.
[0014] Figure 3This is a schematic diagram of a box structure for a splicing packaging structure for server transportation proposed in this utility model.
[0015] Figure 4 For the present utility model in Figure 3 Enlarged view of point A in the image.
[0016] In the attached diagram: 1. Box body; 2. Base plate; 3. First fixing post; 4. Second fixing post; 5. Top cover plate; 6. Grip hole; 7. Limiting block; 8. Connecting groove; 9. Rubber pad; 10. Spring; 11. Telescopic rod; 12. Slot. Detailed Implementation
[0017] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. The components of the embodiments of this application described and marked in the accompanying drawings can be arranged and designed in various different configurations. Therefore, the following detailed description of the embodiments of this application provided in the accompanying drawings is not intended to limit the scope of the claimed application, but merely represents selected embodiments of this application. All other embodiments obtained by those skilled in the art based on the embodiments of this application without inventive effort are within the scope of protection of this application.
[0018] The modular packaging structure for server transportation disclosed in this utility model is mainly applied to scenarios where traditional modular packaging structures for server transportation rely on simple connection methods such as tape and buckles to fix the box and cover, lacking effective limiting and support structures. As a result, the box and cover are prone to relative displacement during transportation, failing to form a stable overall structure and weakening the packaging's ability to resist external impacts.
[0019] Reference Figure 1 , Figure 2 and Figure 3 A modular packaging structure for transporting servers includes a box body 1, with two top cover plates 5 connected to the top outer wall of the box body 1, and multiple gripping holes 6 on the two outer walls of the box body 1. It also includes: a fixing mechanism: the fixing mechanism includes a base plate 2 installed on the bottom outer wall of the box body 1, four second fixing posts 4 evenly distributed on the outer wall of the base plate 2, limit blocks 7 attached to the two outer walls of the second fixing posts 4, and six first fixing posts 3 evenly distributed on the top outer wall of the base plate 2. The outer wall of the box body 1 has six connecting grooves 8, and the outer wall of the top cover plate 5 has four connecting grooves 8; and a vibration damping mechanism: the vibration damping mechanism is located inside the box body 1.
[0020] By installing the base plate 2 on the bottom outer wall of the box body 1, it provides an installation position for the upper components and prevents the bottom of the box body 1 from deforming. At this time, by installing four second fixing posts 4 and six first fixing posts 3 at equal intervals on the outer wall of the base plate 2, the first fixing posts 3 and the second fixing posts 4 and the box body 1 are attached to the outer wall of the upper cover plate 5, thereby limiting the relative displacement of the box body 1 and the upper cover plate 5 in the vertical direction and enhancing the overall height stability of the packaging. At the same time, the limiting blocks 7 attached to the outer walls on both sides of the second fixing posts 4 can further fix the position of the second fixing posts 4 and help enhance the lateral pressure resistance of the fixing mechanism.
[0021] The first fixing post 3 and the second fixing post 4 are both V-shaped structures. The first fixing post 3 and the second fixing post 4 are matched with the outer walls of the box body 1 and the upper cover plate 5. The V-shaped first fixing post 3 and the second fixing post 4 can form a strong support at the splicing point of the box body 1 and the upper cover plate 5, improve the overall rigidity of the packaging, and better protect the internal server.
[0022] Among them, multiple first fixing posts 3 and multiple connecting grooves 8 are matched, and the relative movement between the box body 1 and the upper cover plate 5 is restricted by the cooperation of multiple first fixing posts 3 and multiple connecting grooves 8.
[0023] Specifically, the limiting block 7 is installed on the outer wall of the box 1 and the upper cover plate 5. The limiting block 7 and the second fixing post 4 are engaged to fix the four corners of the box 1 and the upper cover plate 5.
[0024] Reference Figure 3 and Figure 4 In a preferred embodiment, the vibration damping mechanism includes multiple rubber pads 9 installed inside the housing 1. Multiple telescopic rods 11 are connected to the bottom outer wall of the rubber pads 9. Springs 10 are sleeved on the outer wall of the telescopic rods 11. Multiple slots 12 are provided inside the housing 1. The telescopic rods 11 and springs 10 are both installed inside the housing 1.
[0025] By installing the rubber pad 9 on the inner wall of the slot 12, and with the rubber pad 9 in direct contact with the server's feet, multiple telescopic rods 11 and springs 10 are installed on the bottom outer wall of the rubber pad 9. The elastic deformation of the springs 10 and the elastic force of the rubber pad 9 itself buffer the external impact force. At the same time, the telescopic rods 11 provide support for the rubber pad 9, ensuring that the rubber pad 9 can stably return to its original position after being subjected to force. Through the coordinated work of these three, the damage to the server caused by vibration and impact during transportation is effectively reduced.
[0026] The rubber pad 9 is installed on the inner wall of the slot 12, and the slot 12 provides an installation position for the rubber pad 9.
[0027] Reference Figure 1 and Figure 3In a preferred embodiment, the housing 1, the top cover 5, and the limiting block 7 are multi-layered composite structures.
[0028] A multi-layer composite structure is used to improve the impact resistance of the housing 1, the top cover 5, and the limiting block 7.
[0029] Working principle: In use, firstly, insert the enclosure 1 along the six connecting slots 8 on its outer wall, against the outer wall of the six first fixing posts 3 installed on the top outer wall of the base plate 2. Then, by inserting the enclosure 1 along the four corners against the outer walls of the four second fixing posts 4, the enclosure 1 is reinforced. Next, insert the server along the slots 12 inside the enclosure 1. When the server's feet directly contact the rubber pads 9 in the slots 12, and multiple telescopic rods 11 and springs 10 are installed on the bottom outer wall of the rubber pads 9, the elastic deformation of the springs 10 and the elastic force of the rubber pads 9 themselves buffer external impact. Simultaneously, the telescopic rods 11 provide support for the rubber pads 9. To ensure that the rubber pad 9 can stably return to its original position after being subjected to force, the two upper cover plates 5 are connected to the box 1 in the same way as the first fixing post 3 and the second fixing post 4, and the two upper cover plates 5 are installed on the top outer wall of the box 1, thereby achieving the overall wrapping of the server. Since the first fixing post 3 and the second fixing post 4 are both V-shaped structures and match the outer walls of the box 1 and the two upper cover plates 5, a stable and reinforced support can be formed at the splicing point after the box 1 and the two upper cover plates 5 are inserted. At the same time, the limiting block 7 is installed on the outer walls of the box 1 and the upper cover plate 5 and fits tightly against the outer walls on both sides of the second fixing post 4, fixing the four corners of the box 1 and the upper cover plate 5, thus completing the overall splicing of the packaging structure.
[0030] The above description is merely a preferred embodiment of this utility model, but the protection scope of this utility model is not limited thereto. The substitutions may be replacements of some structures, devices, or method steps, or they may be complete technical solutions. Equivalent substitutions or modifications made based on the technical solution and inventive concept of this utility model should all be covered within the protection scope of this utility model.
Claims
1. A modular packaging structure for transporting servers, comprising a box (1), wherein the top outer wall of the box (1) is connected to two upper cover plates (5), and the two outer walls of the box (1) are provided with a plurality of grip holes (6), characterized in that, Also includes: Fixing mechanism: The fixing mechanism includes a bottom plate (2) installed on the bottom outer wall of the box (1), four second fixing posts (4) are evenly distributed on the outer wall of the bottom plate (2), limit blocks (7) are attached to the outer walls on both sides of the second fixing posts (4), six first fixing posts (3) are evenly distributed on the top outer wall of the bottom plate (2), six connecting grooves (8) are provided on the outer wall of the box (1), and four connecting grooves (8) are provided on the outer wall of the upper cover plate (5); Vibration damping mechanism: The vibration damping mechanism is located inside the housing (1).
2. The modular packaging structure for server transportation according to claim 1, characterized in that, Both the first fixing post (3) and the second fixing post (4) are V-shaped structures, and the first fixing post (3) and the second fixing post (4) match the outer walls of the box body (1) and the upper cover plate (5).
3. The modular packaging structure for server transportation according to claim 2, characterized in that, The plurality of first fixing posts (3) and the plurality of connecting slots (8) are matched.
4. The modular packaging structure for server transportation according to claim 1, characterized in that, The limiting block (7) is installed on the outer wall of the box (1) and the upper cover plate (5).
5. The modular packaging structure for server transportation according to claim 1, characterized in that, The vibration damping mechanism includes multiple rubber pads (9) installed inside the housing (1). Multiple telescopic rods (11) are connected to the bottom outer wall of the rubber pads (9). Springs (10) are sleeved on the outer wall of the telescopic rods (11). Multiple slots (12) are provided inside the housing (1). Both the telescopic rods (11) and the springs (10) are installed inside the housing (1).
6. The modular packaging structure for server transportation according to claim 5, characterized in that, The rubber pad (9) is installed on the inner wall of the slot (12).
7. The modular packaging structure for server transportation according to claim 1, characterized in that, The box body (1), the upper cover plate (5) and the limiting block (7) are multi-layer composite structures.