Packaging box and product assembly
By designing a separable, biodegradable annular buffer section and a triangular structure for the packaging box, the problems of low environmental performance and poor stability of existing packaging boxes are solved, thereby improving environmental protection and protective effects.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- GOERTEK INC
- Filing Date
- 2023-05-22
- Publication Date
- 2026-06-19
Smart Images

Figure CN116513623B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of packaging technology, and in particular to a packaging box and product components using the packaging box. Background Technology
[0002] To protect products during transportation, cushioning boxes are typically used. However, in related technologies, the cushioning structure within the packaging box is either directly formed on the box itself or formed using an additional material with good elasticity. Forming the cushioning structure directly on the box makes it an integral part of the main body, potentially damaging it during disassembly and rendering it unusable. Using an additional material with good elasticity, such as blister packs that are difficult to degrade, can cause significant environmental damage. Therefore, both direct and additional elastic material-based cushioning structures in related technologies result in low environmental performance. Furthermore, the stability of the cushioning structure in supporting the product is relatively poor, potentially causing the product to tilt and wobble, thus compromising the protective effect of the packaging. Summary of the Invention
[0003] The main objective of this invention is to provide a packaging box that improves the environmental performance of the packaging box and the protective effect on the product.
[0004] To achieve the above objectives, the packaging box proposed in this invention includes:
[0005] Outer box, wherein the outer box has a receiving cavity; and
[0006] A first buffer structure is detachably disposed within the accommodating cavity. The first buffer structure forms an annular buffer portion with openings at both ends. The projection of the annular buffer portion is triangular in the direction from one opening to the other.
[0007] Optionally, the first buffer structure includes two sub-buffers, each of which forms one of the annular buffer portions;
[0008] The two annular buffer portions are arranged in a cross-layered manner, and each of the two annular buffer portions has an abutting surface on the opposite side;
[0009] One of the two abutting surfaces abuts against the cavity wall of the receiving cavity, and the other abuts against the product located inside the receiving cavity.
[0010] Optionally, one of the two sub-buffers has a slot on the side opposite to its abutting surface, and the annular buffer portion of the other of the two sub-buffers is inserted into the slot on the side opposite to its abutting surface.
[0011] Optionally, each of the sub-buffers includes an enclosing plate and a limiting plate, the enclosing plate enclosing to form the annular buffer portion and having the abutting surface, and the limiting plate being connected to the side of the enclosing plate opposite to the abutting surface;
[0012] The sub-buffer with the slot is defined as the first sub-buffer, and the other sub-buffer is defined as the second sub-buffer. The slot includes a first groove segment and a second groove segment that are connected. The first groove segment is disposed in the enclosing plate of the first sub-buffer, and the second groove segment is disposed in the limiting plate of the first sub-buffer.
[0013] The limiting plate in the second sub-buffer is inserted into the first slot and the second slot, and a portion of the enclosing plate in the second sub-buffer is inserted into the second slot.
[0014] Optionally, the packaging box further includes a retaining strap that passes through two openings of the annular buffer portion and is used to secure the product located in the receiving cavity to the annular buffer portion.
[0015] And / or, the number of the first buffer structure is two, both of which are disposed in the accommodating cavity and located at opposite ends of the packaging box.
[0016] Optionally, the packaging box is defined to have a vertical direction, and the first cushioning structure is provided in the upper and / or lower ends of the packaging box;
[0017] The packaging box also includes a second buffer structure, which is disposed within the accommodating cavity and located on the periphery of the packaging box.
[0018] Optionally, the second buffer structure includes multiple telescopic plates, which are arranged to form an annular structure with openings at both the top and bottom.
[0019] Each of the telescopic panels includes multiple folding segments, which are connected sequentially in a horizontal direction, with each pair of adjacent folding panels arranged at an angle.
[0020] Optionally, the packaging box further includes a base, which is disposed within the receiving cavity and located at the lower end of the packaging box, and the base is provided with an upward-facing limiting groove;
[0021] The limiting groove contains the first buffer structure, and the second buffer structure abuts against the upper surface of the base and is arranged around the limiting groove.
[0022] Optionally, the packaging box further includes an accessory box, which is disposed within the receiving cavity and located at the upper end of the packaging box;
[0023] The accessory box has an installation space inside, and the upper end of the second buffer structure abuts against the lower surface of the accessory box.
[0024] The present invention also proposes a product component, comprising:
[0025] The packaging box, which is the packaging box described above; and
[0026] The product is contained within the packaging box.
[0027] In the use of the packaging box of the present invention, because the first buffer structure has an annular buffer portion with openings at both ends, when the product contained in the accommodating cavity of the packaging box is impacted or vibrated, the first buffer structure can deform inwards accordingly through the annular buffer portion, thereby achieving buffer protection for the product. Furthermore, the first buffer structure in this solution is detachably disposed within the accommodating cavity of the outer box body of the packaging box, so that the first buffer structure will not be damaged when the outer box body of the packaging box is disassembled, and it can be removed for reuse. Simultaneously, the first buffer structure achieves deformation buffering by setting an annular buffer portion with openings at both ends; in other words, the first buffer structure achieves this elastically deformable annular buffer portion through improvements in the mechanical structure. This allows the first buffer structure to be made of biodegradable materials such as paper, replacing the existing method of directly using difficult-to-degrade blister materials to achieve deformation buffering capacity. Therefore, the first buffer structure can be removed and recycled during use, and will not cause environmental damage in the future, thereby improving the environmental performance of the packaging box. Furthermore, the projection of the annular buffer section is triangular in the direction from one opening to the other. This triangular structure provides better stability, reducing the possibility of product tilting or wobbling, thus improving the packaging's protective effect. In other words, the packaging box in this solution improves both its environmental performance and product protection through the modified first buffer structure. Attached Figure Description
[0028] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.
[0029] Figure 1 This is a schematic diagram of the structure of one embodiment of the product component of this application;
[0030] Figure 2 for Figure 1 An exploded structural diagram of a component of the product;
[0031] Figure 3 for Figure 1 A schematic diagram of the product components without the outer casing;
[0032] Figure 4 for Figure 3 An exploded structural diagram of a component of the product;
[0033] Figure 5 for Figure 3 A partial structural diagram of a component of the product;
[0034] Figure 6 for Figure 5 A schematic diagram of the first buffer structure of the product component;
[0035] Figure 7 for Figure 6 Explosion-proof diagram of the first buffer structure
[0036] Figure 8 for Figure 4 A schematic diagram of the second buffer structure of the product component.
[0037] Explanation of icon numbers:
[0038]
[0039]
[0040] The realization of the purpose, functional features and advantages of this application will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation
[0041] 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 a part of the embodiments of this application, and not all of the embodiments. Based on the embodiments of this application, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of this application.
[0042] It should be noted that all directional indicators (such as up, down, left, right, front, back, etc.) in the embodiments of this application are only used to explain the relative positional relationship and movement of each component in a certain specific posture (as shown in the figure). If the specific posture changes, the directional indicator will also change accordingly.
[0043] In this application, unless otherwise expressly specified and limited, the terms "connection," "fixed," etc., should be interpreted broadly. For example, "fixed" can mean a fixed connection, a detachable connection, or an integral part; it can mean a mechanical connection or an electrical connection; it can mean a direct connection or an indirect connection through an intermediate medium; it can mean the internal communication of two components or the interaction between two components, unless otherwise expressly limited. Those skilled in the art can understand the specific meaning of the above terms in this application according to the specific circumstances.
[0044] Furthermore, the use of terms such as "first" and "second" in this application is for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined as "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the word "and / or" throughout the text means including three parallel solutions; for example, "A and / or B" includes solution A, solution B, or a solution that simultaneously satisfies A and B. Furthermore, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of a person skilled in the art to implement them. When the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed in this application.
[0045] Packaging boxes are box structures used to package products, providing them with protection. They are widely used in the electronics industry as well as other machinery industries. Especially during transportation, packaging boxes with cushioning functions are typically used to protect products.
[0046] However, the packaging boxes in this technology still have some areas for improvement during use. Specifically, one drawback is that the cushioning structure inside the packaging box is either formed directly on the box or formed using an additional material with good elasticity. Forming the cushioning structure directly on the box makes it an integral part of the main body, which may be damaged when the box is disassembled, preventing its reuse. Using an additional material with good elasticity, such as blister packs that are difficult to degrade, can cause significant environmental damage. Therefore, both methods of forming the cushioning structure within the packaging boxes result in low environmental performance. Furthermore, given my country's large population, the demand for packaging boxes is enormous, leading to higher requirements for their environmental performance, which current packaging boxes struggle to meet. In addition, the second drawback is that the cushioning structure of this type of packaging box has relatively poor stability in supporting the product, which may make the product prone to tilting and shaking, thus affecting the packaging protection effect.
[0047] Based on the above considerations, and to address the issues of low environmental performance and poor protective effect of packaging boxes in related technologies, this application proposes a novel packaging box. This packaging box improves its environmental performance by designing a first buffer structure that is separable from the outer box body, allowing for easy removal and recycling. Simultaneously, an annular buffer portion with open ends is formed on the first buffer structure, providing deformable elasticity through a mechanical structure, replacing the non-degradable blister material as the buffer structure. Furthermore, the annular buffer portion is designed as a triangular structure, providing better stability and ensuring stable contact with the product. This reduces the possibility of product tilting or shaking, thereby improving the packaging box's protective effect on the product.
[0048] It should be noted that the packaging box proposed in this application can be used to house a drone, a combination of a drone and a charging dock, or even a speaker. Therefore, this application does not specifically limit the object to be packaged; it only requires that the packaging box provide adequate shelter to improve safety during transportation.
[0049] The structure of the packaging box proposed in this application will be explained and described below with specific implementation details. In one embodiment of this application, please refer to the references. Figures 1 to 4The packaging box 10 proposed in this application includes an outer box body 11 and a first buffer structure 13. The outer box body 11 is provided with a receiving cavity 111. The first buffer structure 13 is detachably disposed in the receiving cavity 111. The first buffer structure 13 forms an annular buffer portion 131 with openings at both ends. In the direction from one opening to the other opening of the annular buffer portion 131, the projection of the annular buffer portion 131 is triangular.
[0050] The outer box 11 serves as the main structure of the packaging box 10, forming the receiving cavity 111 to house the product 50. The outer box 11 can be a rectangular prism or a cylindrical structure; this application does not specify the shape of the outer box 11. The material of the outer box 11 can be paper, such as corrugated paper or kraft paper, to reduce manufacturing costs and further improve environmental friendliness. In other embodiments, the outer box 11 can also be made of plastic or other materials; this application does not limit the specific material of the outer box 11. As described above, the receiving cavity 111 is used to house the product 50 to be packaged. Therefore, the shape of the receiving cavity 111 can be arbitrary. Moreover, to improve the adaptability and housing effect, the specific shape of the receiving cavity 111 can be adapted to the shape of the product 50. For example, if the product 50 has a rectangular prism structure, the receiving cavity 111 can be correspondingly set as a rectangular prism cavity.
[0051] The first buffer structure 13 can be used to cushion and protect the product 50 housed within the product 50. Specifically, the first buffer structure 13 forms an annular buffer portion 131 with openings at both ends. This allows the annular buffer portion 131 to undergo corresponding elastic deformation towards the inward side when the product 50 is impacted or vibrated and squeezed, thereby cushioning the product 50. The first buffer structure 13 may only have the annular buffer portion 131, meaning the annular buffer portion 131 constitutes the entirety of the first annular structure. Alternatively, the first buffer structure 13 may include other structures in addition to the annular buffer portion 131. For example, as described below, in addition to the annular buffer portion 131 formed by the enclosing plate 137, it may further include a limiting plate 141. Therefore, this application does not limit the specific structural form of the first buffer structure 13, as long as it includes at least an annular buffer portion 131 with openings at both ends. Furthermore, the first buffer structure 13 is detachably disposed within the receiving cavity 111, meaning that the first buffer structure 13 can be removed from the outer box 11. This includes cases where the first buffer structure 13 is placed directly inside the outer box 11 without any connection, and cases where the first buffer structure 13 has a detachable connection through magnetic attraction or snap-fit. This application does not limit the specifics, as long as it can be removed without damaging the first buffer structure 13. Additionally, the material of the first buffer structure 13 can be paper, such as corrugated paper or kraft paper, to reduce manufacturing costs and further improve environmental friendliness. Of course, in other embodiments, the first buffer structure 13 can also be plastic or other materials. This application does not limit the specific material of the first buffer structure 13, as long as it is easily degradable. Furthermore, the number of first buffer structures 13 can be one, two, or more. This application does not limit the number of first buffer structures 13. The first buffer structure 13 can be positioned at the bottom, top, or periphery of the packaging box 10, or, if there are at least two first buffer structures 13, they can be positioned at different locations within the packaging box 10. Therefore, this application does not limit the position of the first buffer structure 13 within the packaging box 10, and it can be adaptively positioned according to the required buffering position of the product 50 during actual use.
[0052] In the use of the packaging box 10 of the present invention, because the first buffer structure 13 has an annular buffer portion 131 with openings at both ends, when the product 50 placed in the receiving cavity 111 of the packaging box 10 is impacted or vibrated, the first buffer structure 13 can deform accordingly towards the inward through the annular buffer portion 131, thereby achieving buffer protection for the product 50. Furthermore, the first buffer structure 13 in this solution is detachably disposed within the receiving cavity 111 of the outer box body 11 of the packaging box 10, so that the first buffer structure 13 will not be damaged when the outer box body 11 of the packaging box 10 is disassembled, and can be removed for repeated use. Meanwhile, the first buffer structure 13 achieves deformation buffering by providing annular buffer portions 131 with openings at both ends. In other words, the elastically deformable annular buffer portions 131 are obtained through improvements in the mechanical structure of the first buffer structure 13. This allows the first buffer structure 13 to be made of biodegradable materials such as paper, replacing the existing method of directly using difficult-to-degrade blister materials to achieve deformation buffering capacity. Therefore, the first buffer structure 13 can be removed and recycled during use, and will not cause environmental damage in the future, thus improving the environmental performance of the packaging box 10. Furthermore, the projection of the annular buffer portion 131 from one opening to the other is triangular. At this time, the triangular annular buffer portion 131 has better stability, thereby reducing the possibility of the product 50 tilting and shaking, thus improving the packaging protection effect of the product 50. In other words, by improving the first buffer structure 13, the packaging box 10 in this solution simultaneously improves the environmental performance of the packaging box 10 and the packaging protection effect of the product 50.
[0053] Please refer to the reference. Figures 4 to 6 In one embodiment of this application, the first buffer structure 13 includes two sub-buffers 132, each sub-buffer 132 forming an annular buffer portion 131; the two annular buffer portions 131 are arranged in a cross-layered manner, and each of the two annular buffer portions 131 has an abutting surface 133 on its opposite side; one of the two abutting surfaces 133 abuts against the cavity wall of the receiving cavity 111, and the other abuts against the product 50 located in the receiving cavity 111.
[0054] Two annular buffer portions 131 are arranged in a crisscrossing stacked configuration. That is, the two annular buffer portions 131 are arranged sequentially along one direction, and the projections of the center lines of the two annular buffer portions 131 intersect on the projection plane of that direction (including intersections at perpendicular angles and other angles). For example, when the two annular buffer portions 131 are arranged sequentially in a vertical direction, one annular buffer portion 131 can extend in a front-back direction, and the other annular buffer portion 131 can extend in a left-rear direction. At the same time, the upper surface of the upper annular buffer portion 131 is also an abutting surface 133, which can be used to abut and support the product 50 located in the receiving cavity 111; the lower surface of the lower annular buffer portion 131 is also another abutting surface 133, which can be used to abut against the bottom wall of the receiving cavity 111.
[0055] In this embodiment, two sub-buffer members 132 are used to form two overlapping annular buffer portions 131. On one hand, the first buffer structure 13 can abut against the cavity wall of the receiving cavity 111 and the product 50 enclosing the receiving cavity 111 via two abutment surfaces 133, thereby improving the stability of the first buffer structure 13's placement within the receiving cavity 111 and the stability of its contact with the product 50. On the other hand, the overlapping annular buffer portions 131 provide stable support strength in the directions of both annular buffer portions 131. That is, the first buffer structure 13, including the two overlapping annular buffer portions 131, has improved placement stability and support strength, thus facilitating a more stable contact and restraint of the product 50, better reducing the possibility of tilting or swaying of the product 50. Of course, it should be noted that this application is not limited to this; in other embodiments, the first buffer structure 13 may include only one sub-buffer member 132. At this time, the cavity wall of the accommodating cavity 111 can be provided with a groove for accommodating the portion of the sub-buffer 132 facing away from the abutting surface 133, so that the first buffer structure 13 can be placed relatively stably in the accommodating cavity 111. Alternatively, the first buffer structure 13 can be limited by adapting the cavity wall of the accommodating cavity 111 to the peripheral shape of the first abutting surface 133.
[0056] Please refer to the reference. Figure 6 and Figure 7 In one embodiment of this application, one of the two sub-buffers 132 has a slot 134 on the side opposite to its abutting surface 133, and the annular buffer portion 131 of the other of the two sub-buffers 132 is inserted into the slot 134 on the side opposite to its abutting surface 133.
[0057] The slot 134 can be provided on one sub-buffer 132 and pass through the side of the sub-buffer 132 facing the other sub-buffer 132 to allow the insertion of the other sub-buffer 132. For example, when two sub-buffers 132 are arranged vertically, if the slot 134 is provided on the lower sub-buffer 132, then the slot 134 passes through the upper end of the lower sub-buffer 132 to allow a portion of the annular buffer portion 131 in the upper sub-buffer 132 to be inserted.
[0058] In this embodiment, a slot 134 is provided on one sub-buffer 132 to achieve the insertion connection of the two sub-buffers 132. On the one hand, this simplifies the structure between the two, thereby improving the convenience of their connection. Simultaneously, it allows them to be pre-assembled into a single unit, improving the convenience and stability of this part of the structure within the accommodating cavity 111. On the other hand, the slot 134 on one sub-buffer 132 can abut and limit the annular buffer portion 131 on the other sub-buffer 132, further enhancing the strength of the sub-buffer 132 for stable abutment and limiting of the product 50. Of course, this application is not limited to this; in other embodiments, the two sub-buffers 132 can also be fixed by adhesive bonding or other methods, and this application does not specifically limit this.
[0059] Please refer to the reference. Figure 6 and Figure 7 In one embodiment of this application, each sub-buffer 132 includes a surrounding plate 137 and a limiting plate 141. The surrounding plate 137 encloses and forms an annular buffer portion 131 and has an abutment surface 133. The limiting plate 141 is connected to the side of the surrounding plate 137 away from the abutment surface 133. The sub-buffer 132 with a slot 134 is defined as the first sub-buffer 144, and the other sub-buffer 132 is defined as the second sub-buffer 145. The slot 134 includes a first groove segment 135 and a second groove segment 136 that are connected. The first groove segment 135 is disposed in the surrounding plate 137 in the first sub-buffer 144, and the second groove segment 136 is disposed in the limiting plate 141 in the first sub-buffer 144. The limiting plate 141 in the second sub-buffer 145 is inserted into the first groove segment 135 and the second groove segment 136, and a portion of the surrounding plate 137 in the second sub-buffer 145 is inserted into the second groove segment 136.
[0060] The enclosing plate 137 can be used to enclose and form the required annular buffer portion 131, and an abutting surface 133 is formed on one of its outer surfaces. The enclosing plate 137 can be a single, integral structure, or it can be a structure formed by splicing multiple plates together through bonding or other fixing methods; this application does not limit this. The limiting plate 141 can be further inserted for limiting. Specifically, since the end of the enclosing plate 137 facing away from the abutting surface 133 and the slot 134 are in a beveled fit, that is, the enclosing plate 137 and the second slot segment 136 in the second sub-buffer 145 are in a beveled fit, the two may still slide, causing the second sub-buffer 145 to slide out of the first sub-buffer 144. However, through the abutting and limiting action of the limiting plate 141 and the first slot segment 135, the second sub-buffer 145 can be stably clamped and limited in the extending direction of the first sub-buffer 144. The limiting plate 141 can be an integral structure with the enclosure plate 137. Of course, the limiting plate 141 can also be an independent enclosure plate 137, which is then spliced onto the enclosure plate 137 by adhesive or other fixing methods. This application does not limit this.
[0061] In this embodiment, by configuring the sub-buffer 132 as an enclosure plate 137 and a limiting plate 141, the limiting plate 141 can be stably clamped and limited by the two opposing groove walls of the slot 134, based on the annular buffer portion 131 formed by the enclosure plate 137. This improves the stability of the insertion of the two sub-buffers 132, thereby enhancing the overall stability of the second buffer structure 17 and better achieving stable limiting of the product 50. Of course, it should be noted that this application is not limited to this. In other embodiments, when the sub-buffer 132 only includes an enclosure plate 137, the slot 134 can be provided only on the side of the enclosure plate 137 in the first sub-buffer 144 facing away from the abutment surface 133, and the portion of the enclosure plate 137 in the second sub-buffer 145 facing away from the abutment surface 133 can be directly inserted into the slot 134.
[0062] Please refer to the reference. Figure 6 and Figure 7In one embodiment of this application, the enclosure plate 137 includes a first enclosure plate 138, a second enclosure plate 139, and a third enclosure plate 140. One end of the first enclosure plate 138 and one end of the third enclosure plate 140 are respectively connected to one end of the second enclosure plate 139, and an abutment surface 133 is formed on the outer side of the second enclosure plate 139. The limiting plate 141 includes a first sub-plate 142 and a second sub-plate 143. One end of the first sub-plate 142 is connected to the end of the first enclosure plate 138 away from the second enclosure plate 139, and the other end of the first sub-plate 142 is connected to the second sub-plate 143. The second sub-plate 143 extends in a direction away from the abutting surface 133; one end of the second sub-plate 143 is connected to the end of the third enclosure 140 away from the second enclosure 139, and the other end of the second sub-plate 143 extends in a direction away from the abutting surface 133. The second sub-plate 143 is connected to the first sub-plate 142; the first groove segment 135 is provided in the first enclosure 138 and the third enclosure 140 in the first sub-buffer 144, and the second groove segment 136 is provided in the first sub-buffer 142 and the second sub-plate 143 in the first sub-buffer 144.
[0063] The first enclosure 138, the second enclosure 139, and the third enclosure 140 are connected in sequence, with the end of the first enclosure 138 away from the second enclosure 139 and the end of the third enclosure 140 away from the second enclosure 139 close together to form a buffer section. The first sub-plate 142 and the second sub-plate 143 of the limiting plate 141 can be connected to the free ends (i.e., the ends away from the second enclosure 139) of the first enclosure 138 and the third enclosure 140, respectively, and the first sub-plate 142 and the second sub-plate 143 are arranged opposite to each other.
[0064] In this embodiment, the enclosing plate 137 is configured to include a first enclosing plate 138, a second enclosing plate 139, and a third enclosing plate 140, while the limiting plate 141 is configured to include a first sub-plate 142 and a second sub-plate 143. This allows the limiting plate 141 to be integrated with the enclosing plate 137, meaning the sub-buffer 132 can be formed by folding a single piece of cardboard or other material (creases can be formed between the plates for subsequent folding). In this case, the raw materials for forming the sub-buffer 132 are simple and inexpensive, resulting in relatively low raw material costs. Furthermore, the processing is simple, requiring only folding, thus reducing processing costs. Therefore, by folding a single plate to form the sub-buffer 132, both raw material costs and processing costs are reduced, further lowering the manufacturing cost of the packaging box 10. In addition, the first sub-plate 142 and the second sub-plate 143, which are arranged opposite to each other, can also provide a good connection position so that the sub-buffer 132 can be connected and locked after being folded and formed, so as to stably maintain the folded and formed state.
[0065] In one embodiment of this application, the second sub-plate 143 and the first sub-plate 142 are bonded and fixed together.
[0066] Adhesive bonding means that the second sub-board 143 and the first sub-board 142 are bonded and fixed together using glue or double-sided tape.
[0067] In this embodiment, the second sub-plate 143 and the first sub-plate 142 are fixed by adhesive bonding, eliminating the need for connecting structures on the second sub-plate 143 and the first sub-plate 142. This helps ensure that the structural strength of the second sub-plate 143 and the first sub-plate 142 themselves is not damaged. Furthermore, the adhesive bonding method is relatively simple and reliable, thus simplifying the process of bonding the second sub-plate 143 and the first sub-plate 142 and improving the stability of their connection.
[0068] Please refer to Figure 5 In one embodiment of this application, the packaging box 10 further includes a fixing strap 15, which passes through two openings of the annular buffer portion 131 and is used to fix the product 50 located in the receiving cavity 111 to the annular buffer portion 131.
[0069] In this embodiment, the product 50 and the annular buffer portion 131 are further bound together by the fixing strap 15, which helps to improve the stability of the product 50 placed on the first buffer structure 13, further reducing the possibility of the product 50 tilting or shaking, thereby further improving the packaging protection effect of the packaging box 10 on the product 50. The fixing strap 15 can be one, or at least two, and the packaging can pass through the annular buffer portion 131 to further bind and limit both the product 50 and the annular buffer portion 131.
[0070] Please refer to the reference. Figures 3 to 5 In one embodiment of this application, there are two first buffer structures 13, both of which are disposed in the accommodating cavity 111 and located at opposite ends of the packaging box 10.
[0071] In this embodiment, two first buffer structures 13 are provided, enabling them to act as abutments and limits at both ends of the product 50, thereby further improving the packaging protection effect of the product 50. The two first buffer structures 13 can be used to buffer and abut the top and bottom ends of the product 50, respectively. Alternatively, they can buffer and abut the ends of the product 50 in other directions. When the product 50 comprises a composite structure, for example, a charging base 53 and a drone 51 inserted into the charging base 53, the first buffer structure 13 at one end abuts the end of the charging base 53 away from the drone 51, and the first buffer structure 13 at the other end abuts the end of the drone 51 away from the charging base 53. Furthermore, when the packaging box 10 includes a fixing strap 15, a portion of the fixing strap 15 can be used to bind and limit one first buffer structure 13 and the charging base 53, and another portion of the fixing strap 15 can bind and limit the other first buffer structure 13 and the drone 51. In short, with two first buffer structures 13, it is possible to achieve abutment and buffering of the opposite ends of the product 50 contained in the packaging box 10.
[0072] Please refer to the reference. Figure 3 and Figure 4 In one embodiment of this application, the packaging box 10 is defined to have a vertical direction, and a first buffer structure 13 is provided in the upper and / or lower ends of the packaging box 10; the packaging box 10 also includes a second buffer structure 17, which is disposed in the accommodating cavity 111 and located on the periphery of the packaging box 10.
[0073] The packaging box 10 has a first buffer structure 13 inside its upper and / or lower ends. That is, the first buffer structure 13 can be provided only inside the upper end of the packaging box 10, only inside the lower end of the packaging box 10, or both inside both ends of the packaging box 10. In short, the first buffer structure 13 can be used to buffer impacts and vibrations in the vertical direction. The second buffer structure 17 is located around the perimeter of the packaging box 10 and can be used to buffer impacts and vibrations in the horizontal direction. The second buffer structure 17 can be a ring structure including multiple telescopic plates 171 as described below, or it can be a sponge or other elastic buffering object, and it does not have to be a ring structure. This application does not limit the specific structural form of the second buffer structure 17, but it can achieve the buffering of impacts and vibrations in the horizontal direction.
[0074] In this embodiment, the first buffer structure 13 buffers impacts and vibrations in the vertical direction. Since the weight of the product 50 is in the vertical direction, the first buffer structure 13, with its triangular annular buffer portion 131, provides strong stability and stable support for the product 50 in the vertical direction. Furthermore, by cooperating with the second buffer structure 17 located on the periphery of the packaging box 10, even when the product 50 tilts or shakes, the second buffer structure 17 provides cushioning protection, thereby further improving the overall protective effect of the packaging box 10 on the product 50.
[0075] Please refer to Figure 8 In one embodiment of this application, the second buffer structure 17 includes a plurality of telescopic plates 171, which enclose to form an annular structure with openings at both the top and bottom ends; each telescopic plate 171 includes a plurality of folding segments 173, which are connected sequentially in the horizontal direction, and each pair of adjacent folding plates are arranged at an angle.
[0076] Multiple telescopic plates 171 are arranged to form a ring structure with openings at both the top and bottom, meaning that there are corresponding telescopic plates 171 that can extend and retract in both the front-to-back and left-to-right directions. The specific extension and retraction principle of the telescopic plates 171 is as follows: each telescopic plate 171 consists of multiple folded segments 173, with adjacent folded plates arranged at an angle. This allows for deformation and movement space between the folded segments 173 in their sequential arrangement, enabling them to extend and retract when subjected to force. Adjacent folded plates can form right angles, resulting in multiple "V"-shaped structures, providing a larger deformation space and improving the buffering capacity of the second buffer structure 17. Alternatively, adjacent folded plates can form acute angles, resulting in multiple "V"-shaped structures.
[0077] In this embodiment, the second buffer structure 17 is configured as a ring structure with multiple telescopic plates 171, which can provide buffering for the product 50 in all horizontal directions, thereby improving the buffering effect of the second buffer structure 17. On the other hand, the telescopic plates 171 in the second buffer structure 17 are relatively small in volume, which improves the convenience of setting up the second buffer structure 17 in the limited space inside the packaging box 10. Moreover, more importantly, the second buffer structure 17 can be formed by directly folding the plate (a crease can be formed between two adjacent telescopic plates 171), which simplifies the manufacturing process of the second buffer structure 17 and improves the convenience of manufacturing the packaging box 10. At the same time, the second buffer structure 17 can be a single integrated structure, which improves the overall strength and the convenience of its placement. In addition, it should be noted that this application is not limited to this. In other embodiments, it is also possible to directly provide elastic cushioning sponges or the like on the side walls of the packaging box 10.
[0078] Please refer to Figure 8 In one embodiment of this application, the second buffer structure 17 further includes a reinforcing column 175, which extends in the vertical direction and is connected to a reinforcing column 175 for every two adjacent telescopic plates 171.
[0079] The reinforcing post 175 can be located between two adjacent telescopic plates 171. When there are four telescopic plates 171, there can be four reinforcing posts 175. The reinforcing post 175 can be made of the same material as the telescopic plates 171, but its thickness can be increased, and it does not have creases.
[0080] In this embodiment, by setting the reinforcing column 175, the bending strength of the second buffer structure 17 in the vertical direction can be improved, so that the second buffer structure 17 is not easy to bend and can fully exert its buffering capacity for the product 50 in the horizontal direction.
[0081] Please refer to the reference. Figures 2 to 4 In one embodiment of this application, the packaging box 10 further includes a base 18, which is disposed in the receiving cavity 111 and located at the lower end of the packaging box 10. The base 18 is provided with an upward-facing limiting groove 181. A first buffer structure 13 is disposed in the limiting groove 181, and a second buffer structure 17 abuts against the upper surface of the base 18 and is arranged around the limiting groove 181.
[0082] In this embodiment, by accommodating the first buffer structure 13 within the limiting groove 181 of the base 18, the first buffer structure 13 can be further limited by the limiting groove 181, thereby improving the stability of the first buffer structure 13 within the outer box 11 and thus stably cushioning the product 50.
[0083] Please refer to the reference. Figures 2 to 4 In one embodiment of this application, the packaging box 10 further includes an accessory box 19, which is disposed in the accommodating cavity 111 and located at the upper end of the packaging box 10; the accessory box 19 is provided with an installation space 191, and the upper end of the second buffer structure 17 abuts against the lower surface of the accessory box 19.
[0084] The accessory box 19 can be used to form an installation space 191 to accommodate instruction manuals and other accessories. The installation space 191 can be a groove structure, with the opening facing upwards or to one side. Alternatively, the installation space 191 can be a cavity structure. In this case, the accessory box 19 can include a main body and a cover structure that fits onto the main body, allowing access to nearby items located within the installation space 191 by opening the cover.
[0085] In this embodiment, the accessory box 19 provides a space independent of the receiving cavity 111 for accommodating the vicinity of the product 50. This ensures that the placement of the product 50 nearby will not cause space occupation or collision with the product 50 located in the receiving cavity 111, thereby improving the convenience and safety of placement. Furthermore, by having the accessory box 19 and base 18 abut against the upper and lower ends of the second buffer structure 17, the second buffer structure 17 can be clamped and limited (the accessory box 19 and base 18 abut against the top and bottom walls of the receiving cavity 111 respectively, thus clamping the second buffer structure 17 located in the middle), eliminating the need for an additional structure to limit the second buffer structure 17. Therefore, while increasing the accommodating function of the packaging box 10, it also achieves the limitation of the second buffer structure 17, enabling this part of the structure to be used for multiple purposes.
[0086] Please refer to the reference. Figure 1 and Figure 2 In one embodiment of this application, the outer box 11 includes a box body 113 and a box cover 117. The side wall of the box body 113 forms a connecting opening 115 that connects the inner and outer sides of the box body 113. The box cover 117 covers the connecting opening 115, and the box cover 117 and the box body 113 enclose a receiving cavity 111.
[0087] The box body 113 can be a box structure with a connecting opening 115 on one side wall. The box cover 117 can be a single plate structure, or it can be two plate structures arranged opposite each other. In this case, the plate can be fixed by means of bonding or snap-fitting.
[0088] In this embodiment, by providing a connecting opening 115 on the side wall of the outer box 11, the packaging box 10 is designed to open from the side. This allows the accessory box 19 at the top, the second buffer structure 17 in the middle, and the base 18 at the bottom to be clearly exposed after opening the packaging box 10, facilitating the removal of these structures. In other words, this design of the outer box 11 improves the convenience of removing the product 50. It should be noted that this application is not limited to this; in other embodiments, the main body 113 of the outer box 11 may also have a connecting opening 115 at the top, with the box cover 117 positioned at the top of the main body 113. This application does not limit the shape and structure of the outer box 11, as long as it can accommodate the accessory box 19, the second buffer structure 17, and the base 18.
[0089] Please refer to the reference. Figures 1 to 5 This application also proposes a product component 100, which includes a packaging box 10 and a product 50. The specific structure of the packaging box 10 is as described in the above embodiments. Since this product component 100 adopts all the technical solutions of all the above embodiments, it has at least all the beneficial effects brought about by the technical solutions of the above embodiments, and will not be described in detail here. The product 50 is housed within the packaging box 10. Furthermore, the product 50 can be a drone 51, or a combination of a drone 51 and a charging dock 53, or a speaker, etc. This application does not limit the specific type of the product 50, as long as it requires packaging protection.
[0090] The above description is merely a preferred embodiment of this application and does not limit the patent scope of this application. Any equivalent structural transformations made based on the inventive concept of this application and the contents of the specification and drawings of this application, or direct / indirect applications in other related technical fields, are included within the patent protection scope of this application.
Claims
1. A package, characterized in that include: Outer box, wherein the outer box has a receiving cavity; and A first buffer structure is detachably disposed within the accommodating cavity. The first buffer structure forms an annular buffer portion with openings at both ends. In the direction from one opening to the other, the projection of the annular buffer portion is triangular. The first buffer structure includes two sub-buffers, each of which forms an annular buffer portion; the two annular buffer portions are arranged in a cross-stacked manner, and each of the two annular buffer portions has an abutting surface on its opposite side; one of the two abutting surfaces abuts against the cavity wall of the receiving cavity, and the other abuts against the product located in the receiving cavity; Each of the sub-buffers includes an enclosing plate and a limiting plate. The enclosing plate encloses to form the annular buffer portion and has the abutting surface. The limiting plate is connected to the side of the enclosing plate opposite to the abutting surface. One of the two sub-buffers has a slot on the side opposite to its abutting surface and is defined as the first sub-buffer. The other sub-buffer is the second sub-buffer. The slot includes a first groove segment and a second groove segment that are connected. The first groove segment is disposed in the enclosing plate of the first sub-buffer, and the second groove segment is disposed in the limiting plate of the first sub-buffer. The limiting plate of the second sub-buffer is inserted into the first groove segment and the second groove segment, and a portion of the enclosing plate of the second sub-buffer is inserted into the second groove segment.
2. The package of claim 1, wherein The packaging box also includes a fixing strap that passes through two openings of the annular buffer portion and is used to fix the product located in the accommodating cavity to the annular buffer portion. And / or, the number of the first buffer structure is two, both of which are disposed in the accommodating cavity and located at opposite ends of the packaging box.
3. The package of claim 1 or 2, wherein The packaging box is defined to have a vertical direction, and the first buffer structure is provided in the upper and / or lower ends of the packaging box; The packaging box also includes a second buffer structure, which is disposed within the accommodating cavity and located on the periphery of the packaging box.
4. The package of claim 3, wherein The second buffer structure includes multiple telescopic plates, which are arranged to form a ring structure with openings at both the top and bottom. Each of the telescopic panels includes multiple folding segments, which are connected sequentially in a horizontal direction, with each pair of adjacent folding segments arranged at an angle.
5. The package of claim 4, wherein, The packaging box also includes a base, which is disposed within the receiving cavity and located at the lower end of the packaging box. The base is provided with an upward-facing limiting groove. The limiting groove contains the first buffer structure, and the second buffer structure abuts against the upper surface of the base and is arranged around the limiting groove.
6. The package of claim 5, wherein The packaging box also includes an accessory box, which is disposed within the receiving cavity and located at the upper end of the packaging box; The accessory box has an installation space inside, and the upper end of the second buffer structure abuts against the lower surface of the accessory box.
7. A product assembly characterized by, include: The packaging box is the packaging box as described in any one of claims 1 to 6; and a product, which is housed within the packaging box.