An assembled honeycomb tank
By incorporating components such as slots, plates, posts, and screws on the splicing panels, the problem of convenient splicing and stable connection of honeycomb tanks is solved, achieving a stable connection and flexible adjustment between splicing panels, thus enhancing the stability and seismic resistance of the structure.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHIJIAZHUANG SHUNSHI TECH CO LTD
- Filing Date
- 2025-08-20
- Publication Date
- 2026-07-14
AI Technical Summary
Existing honeycomb tanks cannot be easily assembled, and the connections are not secure enough.
The design incorporates components such as slots, plates, springs, posts, and screws on the splicing plates. Through the cooperation of slots, grooves, plates, posts, screws, arc-shaped fixing plates, and screws, multiple splicing plates can be stably connected. Furthermore, through the cooperation of components such as inclined grooves, sliding plates, fixing plates, and bolt grooves, flexible adjustment and stable fixation are provided.
It achieves a stable connection between splicing panels, provides flexible adjustment space and convenient assembly and disassembly, enhances the stability of the connection and its shock and torsional resistance, and facilitates later maintenance and adjustment.
Smart Images

Figure CN224495966U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of honeycomb can technology, specifically to an assembled honeycomb can. Background Technology
[0002] Honeycomb cans generally refer to containers or tanks with a honeycomb structure, typically employing a hexagonal lattice design. This structure effectively increases strength and reduces weight. Honeycomb structures are used in multiple industries, particularly in aerospace, automotive manufacturing, construction, packaging, and energy. This structure is characterized by high strength and low weight because the hexagonal cells maximize stress distribution and effectively utilize the material's strength.
[0003] According to the publicized design of the honeycomb-style tank cluster for sponge cities (Announcement No.: CN 106320781 A), the baseline of the tanks is modeled after a honeycomb pattern, with hexagons arranged in a staggered and closely spaced manner. Each side of each hexagon is shared simultaneously and only with one side of the six adjacent tanks. However, due to structural requirements, the inner walls of the hexagons are made into perfect circles, so that each tank is subjected to circumferential tension internally and supported externally by six arches. A reinforced concrete cover is added to the top of the tanks. The implementation plan includes structural design and arrangements for the bottom plate, tank walls, cover plate structure of the tank cluster, as well as the inner wall shape of the ultra-large tank cluster, the joint positions of the bottom plate, tank body, and cover plate, the detailed structure of the water-stopping system, and the auxiliary management facilities. The slipform technology is used in the tank wall construction.
[0004] The aforementioned patent achieves water storage by mimicking the planar shape of a honeycomb, but it cannot achieve the effect of convenient assembly. Therefore, we propose an assembly-type honeycomb tank. Utility Model Content
[0005] This utility model proposes an assembled honeycomb can, which solves a problem in the related technology of assembled honeycomb cans.
[0006] According to one aspect, at least one embodiment of this disclosure provides a modular honeycomb tank, comprising: a splicing plate, wherein a splicing device is provided on the side of the splicing plate.
[0007] The splicing device includes a slot on the side of the splicing panel, with a groove on its inner side. A retaining plate is fixedly connected to the side of the splicing panel, and a spring is fixedly connected to the top of the retaining plate. One end of the spring is fixedly connected to a retaining post. A threaded opening is provided on the side of the splicing panel, and an arc-shaped fixing plate is slidably connected to the side of the splicing panel. A screw is bolted to the inner side of the threaded opening. The entire splicing device, through the cooperation of components such as the slot, retaining plate, spring, retaining post, threaded opening, arc-shaped fixing plate, and screws, achieves a stable connection between multiple splicing panels while providing flexible adjustment space, thus enhancing the connection stability between the splicing panels.
[0008] For example, in at least one embodiment of this disclosure, a modular honeycomb tank is provided, further comprising: multiple grooves are provided, and the multiple grooves are grouped in pairs. The grouping of multiple grooves helps improve the stability, flexibility, and ease of assembly and disassembly of the splicing device, while also enhancing the connection strength between the splicing plates, enabling the device to adapt to different needs and providing a more reliable and convenient connection method.
[0009] The two grooves are symmetrical about the horizontal axis of the slots, and there are three slots in total. This design, through symmetrical distribution and the arrangement of multiple slots, achieves a more uniform and stable connection between the splicing panels, while providing greater flexibility and ease of operation. The combination of symmetrical grooves and multiple slots enhances the stability of the connection, adapts to different splicing needs, and facilitates disassembly, assembly, and adjustment.
[0010] The three slots are arranged about the longitudinal axis of the splicing plate, and multiple screw holes are provided. This design achieves stability and robustness of the structural connection by setting multiple longitudinally arranged slots and screw holes on the splicing plate, while providing greater flexibility and adjustment space. Multiple slots and screw holes distribute the force, enhance the convenience of assembly and disassembly, and make the overall structure more stable when subjected to external forces.
[0011] Multiple threaded joints are arrayed along the longitudinal axis of the splice plate, and multiple screws are provided. This design, through the multiple longitudinally arrayed threaded joints and screws, improves the connection stability, load-bearing capacity, and seismic and torsional resistance of the splice plate, while also enhancing the flexibility and convenience of the installation process. Multiple fixing points help to distribute stress, ensure the firmness of the connection, and facilitate subsequent maintenance and adjustment.
[0012] Multiple screws are bolted to multiple threaded holes, and three clamping plates are provided. This design, through the bolting of multiple screws to threaded holes, enhances the connection stability and load-bearing capacity of the splicing plates. The three clamping plates provide additional support, ensuring structural stability, enhancing earthquake and torsional resistance, and increasing the ease of installation, adjustment, and disassembly.
[0013] The three clamping plates are arrayed along the longitudinal axis of the splicing plate, and multiple clamping posts are provided. By setting three clamping plates and multiple clamping posts in a longitudinal axis array on the splicing plate, this design can improve the stability, accuracy, and seismic resistance of the overall structure. The cooperative design of the clamping plates and clamping posts enhances the docking and positioning function, load distribution capability, and provides convenience for disassembly and maintenance.
[0014] The multiple locking posts are arranged in pairs, with the two locking posts being symmetrical about the horizontal axis of the locking plate. This symmetrical layout provides balanced mechanical support, making the locking plate more stable during use and less prone to tilting or shifting.
[0015] According to another aspect, at least one embodiment of this disclosure also provides a problem-solving method for a modular honeycomb tank, including: a side-mounted bolt device for the splicing plate, the bolt device including an inclined groove formed on the side of the splicing plate, a sliding plate slidably connected to the inner side of the inclined groove, a fixed plate fixedly connected to one end of the sliding plate, a bolt groove formed on the side of the fixed plate, and a bolt with a washer bolted to the inner side of the bolt groove. This bolt device design, through the cooperation of components such as the sliding plate, fixed plate, bolt groove, and bolts, provides adjustment, fixation, and stability during the installation of the splicing plate. It not only improves the docking accuracy of the splicing plate but also enhances the stability of the structure, prevents loosening or displacement, and provides a more convenient method for disassembly and maintenance.
[0016] For example, in at least one embodiment of this disclosure, a modular honeycomb tank further includes: one end of the sliding plate is located on the displacement trajectory of the locking post, and two bolt grooves are provided, with the two bolt grooves being symmetrical about the transverse axis of the fixing plate. This design achieves precise adjustment and stable fixation of the splicing plate position by aligning the displacement of the sliding plate with the trajectory of the locking post and by symmetrically arranging the bolt grooves. The symmetrical bolt groove layout helps to evenly distribute pressure, increase the stability of the structure, and improve the connection accuracy, making the entire device more robust and reliable, while also facilitating subsequent maintenance and adjustment.
[0017] The working principle and beneficial effects of this utility model are as follows:
[0018] 1. This utility model utilizes components such as slots, grooves, plates, posts, and screws to achieve a secure connection. The operator presses the post to align the plate with the slot. Releasing the post allows a spring to push the post back to its original position, locking it in place with the groove. The operator then reinforces the arc-shaped fixing plate and the two splicing plates with screws. This achieves a stable connection between multiple splicing plates while providing flexible adjustment space, enhancing the stability of the connection between the splicing plates.
[0019] 2. This utility model achieves this through the coordinated operation of components such as inclined grooves, sliding plates, fixing plates, and bolt grooves. When the operator aligns the locking post with the groove, the locking post pushes one end of the sliding plate to move horizontally within the inclined groove. This horizontal movement of the sliding plate causes the fixing plate to move horizontally as well, thus exposing it. The operator can then fix the washer-equipped screws to the wall. This improves the alignment accuracy of the splicing panels, enhances structural stability, prevents loosening or displacement, and provides a more convenient method for disassembly and maintenance. Attached Figure Description
[0020] The preferred embodiments will be described below in a clear and easy-to-understand manner, in conjunction with the accompanying drawings, to further explain the above-mentioned characteristics, technical features, advantages and implementation methods of this utility model.
[0021] Figure 1 This is a schematic diagram of the main structure of this utility model;
[0022] Figure 2 This is a schematic diagram of a single front view structure of this utility model;
[0023] Figure 3 This is a side view of the structure of this utility model;
[0024] Figure 4 This is a schematic diagram of the splicing device structure of this utility model;
[0025] Figure 5 This is a schematic diagram of the top bolt device of this utility model;
[0026] Figure 6 For the present utility model Figure 4 A magnified schematic diagram of A in the middle.
[0027] In the diagram: 1. Splicing plate; 2. Splicing device; 3. Top bolt device; 21. Slot; 22. Groove; 23. Plate; 24. Spring; 25. Column; 26. Threaded opening; 27. Arc-shaped fixing plate; 28. Screw; 31. Slanted groove; 32. Sliding plate; 33. Fixing plate; 34. Bolt groove; 35. Screw with washer. Detailed Implementation
[0028] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the specific implementation methods of this utility model will be described below with reference to the accompanying drawings. Obviously, the drawings described below are merely some embodiments of this utility model. For those skilled in the art, other drawings and other implementation methods can be obtained based on these drawings without any creative effort.
[0029] To keep the drawings concise, only the parts relevant to the utility model are shown schematically in each drawing; these do not represent the actual structure of the product. Furthermore, for ease of understanding, in some drawings, only one of the components with the same structure or function is schematically shown, or only one is labeled. In this document, "a" not only means "only one," but can also mean "more than one," and "several" includes "two" and "more than two."
[0030] In this document, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "linking" should be interpreted broadly. For example, they can refer to fixed connections, detachable connections, or integral connections; they can refer to mechanical connections or electrical connections; they can refer to direct connections or indirect connections through an intermediate medium; and they can refer to the internal connection between 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.
[0031] Furthermore, in the description of this application, the terms "first," "second," etc., are used only to distinguish descriptions and should not be construed as indicating or implying relative importance.
[0032] Example 1
[0033] like Figures 1-6 As shown, it illustrates an assembly-type honeycomb tank according to an embodiment of the present disclosure, including: a splicing plate 1, and a splicing device 2 provided on the side of the splicing plate 1;
[0034] The splicing device 2 includes a slot 21 located on the side of the splicing plate 1. A groove 22 is formed on the inner side of the slot 21. A clamping plate 23 is fixedly connected to the side of the splicing plate 1. A spring 24 is fixedly connected to the top of the clamping plate 23. A locking post 25 is fixedly connected to one end of the spring 24. A screw hole 26 is formed on the side of the splicing plate 1. An arc-shaped fixing plate 27 is slidably connected to the side of the splicing plate 1. A screw 28 is bolted to the inner side of the screw hole 26. The entire splicing device 2, through the cooperation of components such as the slot 21, clamping plate 23, spring 24, locking post 25, screw hole 26, arc-shaped fixing plate 27, and screw 28, achieves a stable connection between multiple splicing plates 1, while providing flexible adjustment space and enhancing the connection stability between the splicing plates 1.
[0035] In some examples, the design also includes multiple grooves 22, with two grooves 22 forming a group. The grouping of multiple grooves 22 helps improve the stability, flexibility, and ease of assembly and disassembly of the splicing device 2, while also enhancing the connection strength between the splicing panels 1, enabling the device to adapt to different needs and providing a more reliable and convenient connection method.
[0036] The two grooves 22 are symmetrical about the horizontal axis of the slots 21, and there are three slots 21. This design, through symmetrical distribution and the arrangement of multiple slots 21, achieves a more uniform and stable connection between the splicing panels 1, while providing greater flexibility and ease of operation. The combination of symmetrical grooves 22 and multiple slots 21 enhances the stability of the connection, adapts to different splicing requirements, and facilitates disassembly, assembly, and adjustment.
[0037] Three slots 21 are arranged about the longitudinal axis of the splicing plate 1, and multiple screw holes 26 are provided. This design achieves stability and robustness of the structural connection by setting multiple longitudinally arranged slots 21 and screw holes 26 on the splicing plate 1, while providing greater flexibility and adjustment space. The multiple slots 21 and screw holes 26 distribute the force, enhance the convenience of assembly and disassembly, and make the overall structure more stable when subjected to external forces.
[0038] Multiple threaded joints 26 are arrayed along the longitudinal axis of the splicing plate 1, and multiple screws 28 are provided. This design, through the multiple longitudinally arrayed threaded joints 26 and screws 28, improves the connection stability, load-bearing capacity, and seismic and torsional resistance of the splicing plate 1, while also enhancing the flexibility and convenience of the installation process. Multiple fixing points help to distribute stress, ensure the firmness of the connection, and facilitate subsequent maintenance and adjustment.
[0039] Multiple screws 28 are bolted to multiple threaded holes 26, and three clamping plates 23 are provided. This design, through the bolting connection of multiple screws 28 and threaded holes 26, enhances the connection stability and load-bearing capacity of the splicing plate 1. The three clamping plates 23 provide additional support, ensuring structural stability, enhancing seismic and torsional resistance, and increasing the ease of installation, adjustment, and disassembly.
[0040] Three clamping plates 23 are arranged in a longitudinal array about the splicing plate 1, and multiple clamping posts 25 are provided. By setting three clamping plates 23 and multiple clamping posts 25 in a longitudinal array on the splicing plate 1, this design can improve the stability, accuracy and seismic resistance of the overall structure. The cooperative design of the clamping plates 23 and clamping posts 25 enhances the docking positioning function, load distribution capability, and provides convenience for disassembly and maintenance.
[0041] Multiple locking posts 25 are arranged in pairs, with the two locking posts 25 being symmetrical about the horizontal axis of the locking plate 23. Through this symmetrical layout, the locking posts 25 can provide balanced mechanical support, making the locking plate 23 more stable during use and less prone to tilting or shifting.
[0042] For example, such as Figures 1-5As shown, the operator first presses down on the locking post 25 by hand, aligning it with the locking slot 21 to ensure a tight fit between the locking plate 23 and the slot 21. When the operator releases their hand, the locking post 25 automatically returns to its original position using the elastic force of the spring 24. The force of the spring 24 ensures that the locking post 25 accurately returns to its original position and locks tightly with the groove 22 in the slot 21, ensuring the stability of the structure. Next, the operator aligns the arc-shaped fixing plate 27 with the two splicing plates 1 and secures them together firmly with screws 28 to further enhance the stability and durability of the overall structure, ensuring that all components are firmly and reliably connected.
[0043] Example 2
[0044] like Figures 1-6 As shown, this illustration depicts another embodiment of a modular honeycomb tank, which is largely the same as the technical solution in Embodiment 1. Therefore, only the differences are described, including: a side-mounted bolt device 3 for the splicing plate 1. The bolt device 3 includes a sloping groove 31, which is formed on the side of the splicing plate 1. A sliding plate 32 is slidably connected to the inner side of the sloping groove 31. A fixing plate 33 is fixedly connected to one end of the sliding plate 32. A bolt groove 34 is formed on the side of the fixing plate 33, and a bolt with a washer 35 is bolted to the inner side of the bolt groove 34. This bolt device 3 design, through the cooperation of components such as the sliding plate 32, the fixing plate 33, the bolt groove 34, and the bolts, provides adjustment, fixation, and stability during the installation of the splicing plate 1. It not only improves the docking accuracy of the splicing plate 1 but also enhances the stability of the structure, prevents loosening or displacement, and provides a more convenient method for disassembly and maintenance.
[0045] In some examples, the design includes a sliding plate 32 with one end positioned on the displacement trajectory of the locking post 25, and two locking slots 34 arranged symmetrically about the transverse axis of the fixing plate 33. This design achieves precise adjustment and stable fixation of the splicing plate 1 by aligning the displacement of the sliding plate 32 with the trajectory of the locking post 25 and by symmetrically arranging the locking slots 34. The symmetrical layout of the locking slots 34 helps to evenly distribute pressure, increase structural stability, and improve connection accuracy, making the entire device more robust and reliable, while also facilitating later maintenance and adjustments.
[0046] For example, such as Figures 1-6As shown, the operator first precisely aligns the locking post 25 with the groove 22. When the locking post 25 and the groove 22 are in close contact, the movement of the locking post 25 pushes one end of the sliding plate 32 to move horizontally along the inclined groove 31. With the horizontal movement of the sliding plate 32, the movement of the sliding plate 32 further drives the fixing plate 33 to move horizontally. The fixing plate 33 gradually protrudes during the movement, facilitating subsequent installation operations. After the fixing plate 33 is exposed in the appropriate position, the operator firmly fixes the washer-equipped screw 35 to the wall through the pre-drilled holes, thereby ensuring the entire device is stable and reliable, completing the installation process.
[0047] It should be noted that the above embodiments are only used to illustrate the technical solution of this utility model and are not intended to limit it. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solution of this utility model without departing from the spirit and scope of the technical solution of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.
Claims
1. A modular honeycomb can body, characterized in that, Includes a splicing panel (1), and a splicing device (2) is provided on the side of the splicing panel (1); The splicing device (2) includes a slot (21), which is opened on the side of the splicing plate (1). The inner side of the slot (21) is provided with a groove (22). A card plate (23) is fixedly connected to the side of the splicing plate (1). A spring (24) is fixedly connected to the top of the card plate (23). A card post (25) is fixedly connected to one end of the spring (24). A screw hole (26) is opened on the side of the splicing plate (1). An arc-shaped fixing plate (27) is slidably connected to the side of the splicing plate (1). A screw (28) is bolted to the inner side of the screw hole (26).
2. The assembled honeycomb can body according to claim 1, characterized in that, The groove (22) has multiple openings, and the multiple grooves (22) are in pairs.
3. The assembled honeycomb can body according to claim 2, characterized in that, The two grooves (22) are symmetrical about the transverse axis of the slot (21), which is provided with three slots (21).
4. The assembled honeycomb can body according to claim 3, characterized in that, The three slots (21) are arranged about the longitudinal axis of the splicing plate (1), and the screw holes (26) are provided in multiple ways.
5. A modular honeycomb can body according to claim 4, characterized in that, Multiple screw holes (26) are arranged along the longitudinal axis of the splicing plate (1), and multiple screws (28) are provided.
6. The assembled honeycomb can body according to claim 5, characterized in that, Multiple screws (28) are bolted to multiple screw holes (26) respectively, and the clamping plate (23) is provided with three.
7. A modular honeycomb can body according to claim 6, characterized in that, The three card plates (23) are arranged about the longitudinal axis of the splicing plate (1), and the card posts (25) are provided in multiples.
8. A modular honeycomb can body according to claim 7, characterized in that, The multiple locking pins (25) are arranged in pairs, and the two locking pins (25) are symmetrical about the horizontal axis of the locking plate (23).
9. A modular honeycomb can body according to claim 8, characterized in that, The top bolt device (3) on the side of the splicing plate (1) includes a groove (31) on the side of the splicing plate (1). A sliding plate (32) is slidably connected to the inner side of the groove (31). A fixing plate (33) is fixedly connected to one end of the sliding plate (32). A bolt groove (34) is provided on the side of the fixing plate (33). A bolt with a washer (35) is bolted to the inner side of the bolt groove (34).
10. A modular honeycomb can body according to claim 9, characterized in that, One end of the sliding plate (32) is located on the displacement trajectory of the locking post (25), and there are two bolt grooves (34), which are symmetrical about the horizontal axis of the fixing plate (33).