Anti-vibration transport special industrial computer lining honeycomb board protection box
By combining a rectangular outer frame and a honeycomb inner lining with stepped through-hole buffer columns, the problem of weak buffering in the protective box in a vibration environment is solved, realizing all-round seismic protection for the industrial control computer and enhancing the seismic performance and buffering effect of the protective box.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN YUEFEI IND CONTROL INTELLIGENT TECH CO LTD
- Filing Date
- 2025-07-14
- Publication Date
- 2026-06-26
AI Technical Summary
Existing protective enclosures cannot effectively absorb and dissipate external energy in vibration environments, leading to malfunctions of industrial control equipment. Furthermore, traditional buffer materials are prone to aging and deformation under long-term vibration, failing to provide reliable seismic protection continuously.
The industrial control computer adopts a rectangular outer frame structure with honeycomb panel inner protective box. Combined with honeycomb lining and stepped through-hole buffer columns, it forms a rigid-flexible earthquake-resistant system. The honeycomb structure absorbs and disperses impact energy, and the stepped through holes gradually dissipate energy, enhancing corner protection.
It provides comprehensive protection for industrial control computers, improves the seismic performance of the protective box in vibration environments, avoids structural damage caused by uneven stress, and the honeycomb structure has better stability than traditional materials, with significant continuous energy dissipation effect.
Smart Images

Figure CN224409996U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of protective box technology, and in particular to a protective box with honeycomb panel lining for industrial control computers specifically designed for earthquake-resistant transportation. Background Technology
[0002] In fields such as industrial automation control and intelligent equipment, industrial control computers (ICCs) serve as core control devices, and their stable operation is crucial to the reliability of the entire system. However, ICCs are often used in scenarios with complex vibration environments, such as industrial production lines, machinery sites, and transportation vehicles. The continuous vibrations and sudden impacts in these scenarios can easily damage the electronic components, circuit boards, and connecting parts inside the ICC, leading to equipment failure, data loss, or even system shutdown, which can seriously affect industrial production and equipment operation.
[0003] Existing traditional protective enclosures mostly use a single material structure, such as ordinary metal plates or plastic plates, which have limited vibration damping performance and cannot effectively absorb and dissipate external vibration energy. Although some protective enclosures add simple cushioning materials inside, such as foam and rubber pads, the cushioning effect of these materials is limited by the material properties and structural design. Under long-term vibration, they are prone to aging and deformation, resulting in a decline in cushioning performance and making it difficult to continuously provide reliable shock protection for industrial control computers.
[0004] Therefore, this utility model provides a protective box with honeycomb panels lining an industrial control computer, specifically designed for earthquake-resistant transportation. Utility Model Content
[0005] The purpose of this invention is to overcome the shortcomings of existing technologies and provide a protective box with honeycomb panels for industrial control computers specifically designed for earthquake-resistant transportation.
[0006] To achieve the above objectives, the present invention adopts the following technical solution: a protective box for industrial control computers with honeycomb panels for earthquake-resistant transportation, comprising an outer panel assembly, wherein the outer panel assembly comprises a side panel, both ends of the side panel are fixedly connected to a vertical plate, and the bottom end of the side panel is fixedly connected to a bottom plate;
[0007] The corner protection component includes buffer columns fixedly connected to both sides of the top of the base plate. The buffer columns have outer through holes on their inner and outer sides, and an inner through hole at the center of the buffer column. The inner and outer through holes are designed to increase in size sequentially.
[0008] In a preferred embodiment, the side plates, upright plates, and bottom plates are all provided with honeycomb linings.
[0009] In a preferred embodiment, the diameter of the inner through hole of the buffer column is smaller than the diameter of the outer through hole, forming a stepped through hole structure.
[0010] In a preferred embodiment, the side plate and the upright plate are fixedly connected to form the side frame structure of the protective box, and the side plate and the bottom plate are fixedly connected to form the bottom support structure.
[0011] In a preferred embodiment, the corner protection components are symmetrically arranged on the left and right sides of the top of the base plate, and each corner protection component includes at least one buffer post.
[0012] In a preferred embodiment, the honeycomb liner is tightly fitted to the inner walls of the side panels, upright panels, and bottom panel to form a continuous honeycomb-shaped buffer layer.
[0013] In a preferred embodiment, the upright plate is vertically fixed to both ends of the side plate, and the bottom plate is horizontally fixed to the bottom end of the side plate, together forming a rectangular cross-section protective box outer frame.
[0014] Compared with the prior art, the advantages and positive effects of this utility model are as follows:
[0015] This invention utilizes a rectangular outer frame formed by the side plates, upright plates, and bottom plate of the outer panel assembly to provide rigid support. This frame, along with a tightly fitted honeycomb lining on the inner wall, forms a continuous buffer layer. The deformation of the honeycomb structure absorbs and disperses impact energy, which in turn drives the buffer columns of the corner protection assembly. The stepped structure, composed of outer and inner through-holes, provides initial buffering at corners, with the outer through-holes first absorbing the energy and the inner through-holes further dissipating it. This design achieves layered absorption of external impacts: the outer frame bears the initial load, the honeycomb lining dissipates the main energy, and the corner buffer columns specifically reinforce weak points, forming a rigid-flexible earthquake-resistant system. Furthermore, the honeycomb structure exhibits superior stability compared to traditional foam materials, and the stepped through-holes continuously dissipate energy through geometric deformation. This design solves the problem of weak buffering at stress-concentrated areas in traditional protective boxes. Attached Figure Description
[0016] Figure 1 A perspective view of the honeycomb panel protective box for industrial control computers used in earthquake-resistant transportation, provided by this utility model;
[0017] Figure 2 A schematic diagram of the honeycomb lining structure of the industrial control computer inner honeycomb panel protective box for earthquake-resistant transportation provided by this utility model;
[0018] Figure 3 for Figure 2 Enlarged view of point A in the image;
[0019] Figure 4 A schematic diagram of the buffer column structure of the honeycomb panel protective box for earthquake-resistant transportation of industrial control computers provided by this utility model;
[0020] Figure 5A schematic diagram of the corner protection component of the honeycomb panel lining protective box for industrial control computers used in earthquake-resistant transportation provided by this utility model.
[0021] Legend:
[0022] 1. Outer panel assembly; 11. Side panel; 12. Vertical panel; 13. Base plate; 14. Honeycomb lining;
[0023] 2. Corner protection component; 21. Buffer post; 22. Outer through hole; 23. Inner through hole. Detailed Implementation
[0024] 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.
[0025] like Figure 1 , Figure 2 and Figure 4 As shown, this embodiment provides a technical solution: a protective box for industrial control computers with honeycomb panels for earthquake-resistant transportation, including an outer panel assembly 1. The outer panel assembly 1 includes side panels 11, with upright plates 12 fixedly connected to both ends of the side panels 11 and a bottom plate 13 fixedly connected to the bottom end of the side panels 11. Honeycomb liners 14 are provided inside the side panels 11, upright plates 12, and bottom plate 13. The side panels 11 and upright plates 12 are fixedly connected to form the side frame structure of the protective box, and the side panels 11 and bottom plate 13 are fixedly connected to form the bottom support structure. The honeycomb liners 14 are tightly fitted to the inner walls of the side panels 11, upright plates 12, and bottom plate 13, forming a continuous honeycomb-shaped buffer layer. The upright plates 12 are vertically fixed to both ends of the side panels 11, and the bottom plate 13 is horizontally fixed to the bottom end of the side panels 11, together forming a rectangular cross-section outer frame of the protective box.
[0026] The two ends of the side plate 11 are fixedly connected to the upright plate 12, and the bottom end is fixedly connected to the bottom plate 13. This connection method constitutes the main frame of the protective box. The side plate 11 and the upright plate 12 form a side frame structure, which provides side support and protection for the industrial control computer, preventing side collisions and impacts from damaging the industrial control computer. The side plate 11 and the bottom plate 13 form a bottom support structure, ensuring that the protective box has stable bottom support during placement and transportation. The honeycomb liner 14 is tightly attached to the inner wall of the side plate 11, the upright plate 12 and the bottom plate 13, forming a continuous honeycomb buffer layer. The honeycomb structure has good buffer performance. When the protective box is impacted by external force, the honeycomb liner 14 can effectively absorb and disperse the impact energy, reducing the direct impact of the impact force on the industrial control computer.
[0027] The upright plate 12 is vertically fixed to both ends of the side plate 11, and the bottom plate 13 is horizontally fixed to the bottom end of the side plate 11, together forming a rectangular cross-section outer frame of the protective box. This rectangular cross-section outer frame structure gives the protective box a regular shape, making it easy to stack and store. At the same time, it ensures the overall rigidity and strength of the protective box, enabling it to withstand certain external pressure and impact, and providing all-round protection for the internal industrial control computer.
[0028] like Figure 3 and Figure 5 As shown, the corner protection component 2 includes buffer posts 21 fixedly connected to both sides of the top of the base plate 13. The buffer posts 21 have outer through holes 22 on their inner and outer sides, and an inner through hole 23 at the center of the buffer posts 21. The inner through hole 23 and the outer through hole 22 are designed to be from small to large. The corner protection components 2 are symmetrically arranged on the left and right sides of the top of the base plate 13, and each corner protection component 2 includes at least one buffer post 21. The diameter of the inner through hole 23 of the buffer post 21 is smaller than the diameter of the outer through hole 22, forming a stepped through hole structure.
[0029] The buffer pillars 21 are fixedly connected to both sides of the top of the base plate 13 and are positioned at the junction of the upright plate 12 and the base plate 13. This location is a corner where the protective box experiences concentrated stress and is prone to collisions and impacts during transportation. The buffer pillars 21 have outer through holes 22 on their outer sides and an inner through hole 23 in their center. The inner through hole 23 and the outer through hole 22 are designed to increase in size sequentially, forming a stepped through hole structure. This stepped through hole structure can gradually absorb and dissipate impact energy when the buffer pillars 21 are impacted, through the cooperation of through holes of different diameters, thus playing a good buffering role. The corner protection components 2 are symmetrically arranged on the left and right sides of the top of the base plate 13. The design ensures even protection at the corners on both sides of the protective box, preventing damage to one corner due to uneven force distribution and thus maintaining the structural integrity of the entire protective box. Each corner protection component 2 includes at least one buffer post 21. The number of buffer posts 21 can be increased to improve buffering performance based on actual protection needs. The design of the inner through hole 23 of the buffer post 21 having a smaller diameter than the outer through hole 22 ensures that during the transmission of impact force, the outer through hole 22 contacts the impacting object first and begins to buffer, while the inner through hole 23 continues to play its role, further absorbing impact energy and enhancing the buffering effect, effectively protecting the safety of the industrial control computer during transportation.
[0030] Working principle:
[0031] like Figure 1 - Figure 5 As shown:
[0032] In use: First, the outer panel assembly 1 of the protective box, consisting of side panels 11, upright panels 12, and a bottom panel 13, forms a rectangular outer frame through a fixed connection. Since the inner walls of the side panels 11, upright panels 12, and bottom panel 13 are tightly fitted with honeycomb linings 14, forming a continuous honeycomb-shaped buffer layer, the impact force will cause the honeycomb lining 14 to deform. The unique buffering performance of the honeycomb structure can effectively absorb and disperse some of the impact energy, reducing the direct transmission of the impact force to the internal industrial control computer. Then, the corner protection assembly 2 located at the connection between the upright panel 12 and the bottom panel 13 begins to function. The buffer posts 21, symmetrically arranged on both sides of the top of the bottom panel 13, have internal... The outer through-hole 22 and the inner through-hole 23 form a stepped through-hole structure with increasing size. When the impact is transmitted to the corner of the protective box, which is a concentrated area of force, the outer through-hole 22 of the buffer column 21 first contacts the impacting object and undergoes initial deformation, thus absorbing the impact energy. As the impact force continues to be transmitted, the inner through-hole 23, due to its smaller diameter, further consumes the impact energy. Through the cooperation of through-holes with different diameters, the impact energy is gradually absorbed. This stepped through-hole structure and the symmetrical arrangement of the buffer columns 21 ensure that the left and right corners can bear the impact evenly, avoiding structural damage due to uneven force distribution.
[0033] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present utility model without departing from the technical solution of the present utility model shall still fall within the protection scope of the technical solution of the present utility model.
Claims
1. A protective box lined with honeycomb panels for industrial control computers used in earthquake-resistant transportation, characterized in that, The outer panel assembly (1) includes a side panel (11), with upright plates (12) fixedly connected to both ends of the side panel (11) and a bottom plate (13) fixedly connected to the bottom end of the side panel (11). The corner protection component (2) includes buffer columns (21) fixedly connected to both sides of the top of the base plate (13). The buffer columns (21) have an outer through hole (22) on the inner side and an inner through hole (23) at the center of the buffer column (21). The inner through hole (23) and the outer through hole (22) are designed to be from small to large.
2. The protective box with honeycomb panel lining for industrial control computers specifically for earthquake-resistant transportation as described in claim 1, characterized in that: The side plate (11), the upright plate (12) and the bottom plate (13) are all provided with honeycomb lining (14).
3. The protective box with honeycomb panel lining for industrial control computers specifically for earthquake-resistant transportation as described in claim 1, characterized in that: The diameter of the inner through hole (23) of the buffer column (21) is smaller than the diameter of the outer through hole (22), forming a stepped through hole structure.
4. The protective box with honeycomb panel lining for industrial control computers specifically for earthquake-resistant transportation as described in claim 1, characterized in that: The side plate (11) and the upright plate (12) are fixedly connected to form the side frame structure of the protective box, and the side plate (11) and the bottom plate (13) are fixedly connected to form the bottom support structure.
5. The protective box with honeycomb panel lining for industrial control computers specifically for earthquake-resistant transportation as described in claim 1, characterized in that: The corner protection components (2) are symmetrically arranged on the left and right sides of the top of the base plate (13), and each corner protection component (2) includes at least one buffer post (21).
6. The protective box with honeycomb panel lining for industrial control computers specifically for earthquake-resistant transportation as described in claim 2, characterized in that: The honeycomb liner (14) is tightly fitted to the inner walls of the side plate (11), the upright plate (12) and the bottom plate (13) to form a continuous honeycomb buffer layer.
7. The protective box with honeycomb panel lining for industrial control computers specifically for earthquake-resistant transportation as described in claim 1, characterized in that: The upright plate (12) is vertically fixed to both ends of the side plate (11), and the bottom plate (13) is horizontally fixed to the bottom end of the side plate (11), together forming a rectangular cross-section protective box outer frame.