Storage cavity spacing structure, matching container body and storage container

By designing a modular spacer structure, the problem of fixed spacer positions was solved, enabling flexible adjustment and customized design of the storage cavity space to meet users' individual needs.

CN224393333UActive Publication Date: 2026-06-23YANTAI GREENERY TOOLS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
YANTAI GREENERY TOOLS CO LTD
Filing Date
2025-07-04
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

In the existing technology, the installation position of the partition plate is fixed, which makes it difficult to flexibly adjust the size and position of the storage cavity partition space according to the needs.

Method used

A storage cavity spacing structure is provided, including multiple spacers, each spacer having a connecting structure in the length and thickness directions, allowing for longitudinal and transverse splicing. Flexible splicing is achieved through locking strips and receiving slots to adapt to different needs.

Benefits of technology

It enables flexible adjustment of the storage cavity spacing to meet users' personalized needs, provides customized storage solutions, and is easy to use.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application provides a storage cavity spacing structure, a matching container body and a storage container. The storage cavity spacing structure comprises a plurality of spacing pieces. Each spacing piece has a first end face and a second end face, and a first side face and a second side face. The first end face is provided with a first connecting structure which is configured to be connectable with a fifth connecting structure of a side wall of a storage cavity. The second end face is provided with a second connecting structure which is configured to be connectable with a sixth connecting structure of the side wall of the storage cavity and a first connecting structure of another spacing piece. The first side face is provided with a third connecting structure which is configured to be connectable with a second connecting structure of another spacing piece. The second side face is provided with a fourth connecting structure which is configured to be connectable with a first connecting structure of another spacing piece. The spacing piece provided by the application can be flexibly spliced in the longitudinal direction and the transverse direction, so that the number, size and position of the spacing spaces of the storage cavity can be flexibly adjusted according to requirements.
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Description

Technical Field

[0001] This application relates to the field of storage container technology, and in particular to a storage cavity spacer structure, a matching container body, and a storage container. Background Technology

[0002] Toolboxes, as a commonly used storage and carrying device, are widely used in various scenarios such as home, repair, industry, and medical.

[0003] A toolbox includes a box body, the interior of which forms a storage cavity for holding items. When using a toolbox, it is often necessary to store multiple different items in the same toolbox. To prevent different items from being mixed together and difficult to retrieve or find, related technologies have partitions installed inside the storage cavity to separate the space within the storage cavity, thereby facilitating the categorized storage of different items.

[0004] However, in related technologies, the installation position of the partition is usually relatively fixed, which results in a relatively fixed size and position of the space separated by the partition in the storage cavity, making it difficult to flexibly adjust the size and position of the partition space according to the needs. Utility Model Content

[0005] This application provides a storage cavity partition structure, a matching container body, and a storage container to solve the technical problem in related technologies that the partition plate is difficult to flexibly adjust the size and position of the partition space according to requirements.

[0006] The embodiments of this application provide the following technical solutions to solve the above-mentioned technical problems:

[0007] This application provides a storage cavity spacer structure, including a plurality of spacers, each of which has a first end face and a second end face in the length direction, and a first side face and a second side face in the thickness direction;

[0008] The first end face is provided with a first connection structure, which is configured to connect with a fifth connection structure on the side wall of the storage cavity;

[0009] The second end face is provided with a second connection structure, and the first connection structure is configured to be able to connect with the sixth connection structure of the storage cavity sidewall and to connect with the first connection structure of another spacer.

[0010] The first side is provided with a third connecting structure, which is configured to connect with the second connecting structure of another spacer.

[0011] The second side is provided with a fourth connection structure, which is configured to connect with the first connection structure of another spacer.

[0012] The beneficial effects of this application's embodiments: The storage cavity spacing structure provided in this application's embodiments includes multiple spacers, which can be spliced ​​together horizontally and vertically to create lateral or longitudinal spacing within the storage cavity. The spacers have a uniform structure, facilitating modular manufacturing. Users can flexibly choose the number of spacers and design the splicing method according to their spatial spacing requirements. Thus, each user can obtain a storage cavity that meets their specific spacing needs, and each user can obtain a customized storage cavity that meets their requirements. The spacers provided in this application's embodiments can be flexibly spliced ​​both vertically and horizontally, thereby allowing for flexible adjustment of the number, size, and position of the storage cavity spacing spaces according to requirements, making it convenient to use.

[0013] In one possible implementation, the first connecting structure and the third connecting structure are locking protrusions; the second connecting structure and the fourth connecting structure are receiving grooves that cooperate with the locking protrusions.

[0014] In one possible implementation, at least one side of the first connecting structure is provided with a protrusion.

[0015] In one possible implementation, the second connection structure includes a first side and a second side, with the receiving groove formed between the first side and the second side;

[0016] The first side includes a plurality of spaced first mating pieces, and the second side includes a plurality of spaced second mating pieces, with the plurality of first mating pieces and the plurality of second mating pieces being alternately arranged.

[0017] In one possible implementation, the first side has two adjacent and spaced first borders, with some edges of the first borders extending on the edge of the first side, and the card protrusion structure is provided between two adjacent edges of the two first borders.

[0018] In one possible implementation, the second side has two adjacent and spaced second borders, three edges of which extend along the edge of the second side, and two adjacent edges of the two second borders cooperate to form the receiving groove.

[0019] This application embodiment also provides a mating container body, which is configured to be installed inside a storage container. The mating container body includes a mating container body body and the storage cavity partition structure described in any of the above embodiments.

[0020] The container body has a storage cavity, the storage cavity has a fifth connecting structure on at least the first side wall and a sixth connecting structure on at least the second side wall; the first side wall and the second side wall are the two opposite side walls of the storage cavity, and the distance between the two side walls is configured to allow for the splicing and installation of at least one spacer of the storage cavity spacer structure.

[0021] The mating container body provided in this application embodiment can be installed inside a storage container, enabling flexible spatial partitioning even in storage containers lacking space separation functionality. The beneficial effects of the storage cavity of the mating container body being flexibly partitioned by spacers are the same as the beneficial effects of the aforementioned storage cavity partitioning structure, and will not be repeated here.

[0022] In one possible implementation, both the fifth and sixth connecting structures include a plurality of spaced-apart second protrusions and a second receiving groove formed between any two adjacent second protrusions. The plurality of second protrusions on the first sidewall are staggered with the plurality of second protrusions on the second sidewall. The second protrusions are configured to receive the second connecting structure, and the second receiving groove is configured to receive the first connecting structure.

[0023] In one possible implementation, each spacer of the storage cavity spacer structure has a limiting groove on its bottom end face in the height direction, and the limiting groove extends in the length direction of the spacer.

[0024] The bottom wall of the storage cavity is provided with at least one limiting strip, wherein at least one of the limiting strips extends in the length direction of the storage cavity, and the limiting strip is configured to cooperate with the limiting groove.

[0025] This application embodiment also provides a storage container, which includes a container body and a storage cavity spacer structure as described in any of the above embodiments;

[0026] The container body has a storage cavity, the storage cavity has at least a fifth connecting structure on the first side wall, and the storage cavity has at least a sixth connecting structure on the second side wall; the first side wall and the second side wall are the two opposite side walls of the storage cavity, and the distance between the two side walls is configured to allow for the splicing and installation of at least one spacer of the storage cavity spacer structure.

[0027] The beneficial effects of the storage container provided in this application embodiment are the same as those of the storage cavity spacer structure described above, and will not be repeated here.

[0028] In one possible implementation, each of the spacers has a limiting groove on its bottom end face in the height direction, and the limiting groove extends in the length direction of the spacer.

[0029] The bottom wall of the storage cavity is provided with at least one limiting strip, wherein at least one of the limiting strips extends in the length direction of the storage cavity, and the limiting strip is configured to cooperate with the limiting groove.

[0030] This application embodiment also provides a storage container, which includes a container body and a matching container body as described in any of the above embodiments, wherein the container body has a receiving cavity;

[0031] The number of the mating containers is one or more, and each of the mating containers is installed in the accommodating cavity.

[0032] The beneficial effects of the storage container provided in this application are the same as those of the aforementioned matching container body, and will not be repeated here. In addition to the technical problems solved by this application, the technical features constituting the technical solution, and the beneficial effects brought about by these technical features, as described above, other technical problems solved by the storage cavity spacing structure, matching container body, and storage container provided in this application, other technical features included in the technical solution, and the beneficial effects brought about by these technical features will be further explained in detail in the specific embodiments. Attached Figure Description

[0033] The accompanying drawings, which are incorporated in and form part of this specification, illustrate embodiments consistent with this application and, together with the description, serve to explain the principles of this application.

[0034] Figure 1 This is a schematic diagram of the spacer in an embodiment of this application;

[0035] Figure 2 This is a schematic diagram of the spacer from another perspective in an embodiment of this application;

[0036] Figure 3 This is a schematic diagram of the container body used in an embodiment of this application;

[0037] Figure 4 This is a schematic diagram of another container body in accordance with an embodiment of this application.

[0038] Explanation of reference numerals in the attached figures:

[0039] 100. Spacer;

[0040] 110. First end face; 120. Second end face; 130. First side face; 140. Second side face; 150. Bottom end face; 160. Limiting groove;

[0041] 111. First connecting structure; 112. Protrusion;

[0042] 121. Second connecting structure; 122. First side; 123. Second side; 124. First mating piece; 125. Second mating piece; 126. Receiving slot;

[0043] 131. Third connecting structure; 132. First border;

[0044] 141. Fourth connecting structure; 142. Second border;

[0045] 200. To fit the container body;

[0046] 210. Storage cavity; 220. First sidewall; 230. Second sidewall; 240. Fifth connecting structure; 250. Sixth connecting structure; 260. Bottom wall; 270. Limiting strip;

[0047] 241. Second card protrusion; 242. Second receiving slot.

[0048] The accompanying drawings illustrate specific embodiments of this application, which will be described in more detail below. These drawings and descriptions are not intended to limit the scope of the concept in any way, but rather to illustrate the concept of this application to those skilled in the art through reference to particular embodiments. Detailed Implementation

[0049] In related technologies, the length of the spacers used to partition the storage cavities is preset during production and processing. When partitioning the storage cavities, their installation positions are relatively fixed, resulting in a relatively fixed size, position, and number of spaces partitioned by the spacers. This makes it difficult to flexibly adjust the size, position, and number of partition spaces according to requirements.

[0050] In view of this, this application modifies the structure of the spacers so that they can be spliced ​​together horizontally and vertically to create horizontal or vertical spacing in the storage cavity. The uniform structure of the spacers facilitates modular manufacturing. Users can flexibly choose the number of spacers to use and design the splicing method of the spacers according to their needs for space spacing size, location, and quantity. As a result, each user can obtain a storage cavity that meets their own spacing requirements, and thus each user can obtain a customized storage cavity that meets their needs.

[0051] 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. Example

[0052] like Figure 1, Figure 2 , Figure 3 and Figure 4 As shown, the storage cavity spacing structure provided in this application embodiment includes a plurality of spacers 100, each spacer 100 being spaced along its length (e.g., ...). Figure 1 It has a first end face 110 and a second end face 120 in the X direction (as in the image), and in the thickness direction (e.g., ... Figure 1 The spacer 100 has a first side surface 130 and a second side surface 140 in the Y direction. That is, the two opposite end surfaces of the spacer 100 in the length direction X are the first end surface 110 and the second end surface 120, respectively, and the two opposite sides of the spacer 100 in the thickness direction Y are the first side surface 130 and the second side surface 140, respectively.

[0053] In this embodiment, the first end face 110 is provided with a first connecting structure 111, which is configured to be connected to the fifth connecting structure 240 on the side wall of the storage cavity 210. The second end face 120 is provided with a second connecting structure 121, which is configured to be connected to the sixth connecting structure 250 on the side wall of the storage cavity 210 and to the first connecting structure 111 of another spacer 100. The first side face 130 is provided with a third connecting structure 131, which is configured to be connected to the second connecting structure 121 of another spacer 100. The second side face 140 is provided with a fourth connecting structure 141, which is configured to be connected to the first connecting structure 111 of another spacer 100. In other words, for any two spacers 100, the first connection structure 111 of one spacer 100 can be connected to the second connection structure 121 of the other spacer 100; for any two spacers 100, the first connection structure 111 of one spacer 100 can be connected to the fourth connection structure 141 of the other spacer 100; and for any two spacers 100, the second connection structure 121 of one spacer 100 can be connected to the third connection structure 131 of the other spacer 100.

[0054] For example, such as Figure 4As shown, the width of the storage cavity 210 matches the length of the spacer 100. The first connecting structure 111 and the second connecting structure 121 of the spacer 100 are connected to the fifth connecting structure 240 and the sixth connecting structure 250 of the storage cavity 210, respectively. Users can select spacers 100 to space the space in the length direction of the storage cavity 210 according to their needs. One or more spacers 100 can be spliced ​​between two adjacent spacers 100 in the length direction as needed to separate the space between adjacent spacers 100 in the width direction of the storage cavity 210. Of course, in other embodiments, the width of the storage cavity 210 can also be set to accommodate multiple spliced ​​spacers 100, that is, the spacers 100 can be spliced ​​together horizontally and vertically within the storage cavity 210 to provide horizontal or vertical spacing. The spacers 100 of the storage cavity spacing structure provided in this application embodiment can be spliced ​​together horizontally and vertically to space the storage cavity 210 laterally or vertically. The spacers 100 have a uniform structure, which facilitates modular processing. Users can flexibly choose the number of spacers 100 and design the splicing method of the spacers 100 according to the space spacing requirements. Thus, each user can obtain a storage cavity 210 that meets their own spacing requirements, and each user can obtain a customized storage cavity 210 that meets their own needs. The spacers 100 can be flexibly spliced ​​in the vertical and horizontal directions, so the number of storage cavity 210 spacing spaces and the size of each spacing space can be flexibly adjusted according to the requirements, which is convenient to use.

[0055] It should be noted that in this application, "multiple" includes two.

[0056] For example, the first connecting structure 111 and the third connecting structure 131 are locking protrusions; the second connecting structure 121 and the fourth connecting structure 141 are receiving grooves 126 that cooperate with the locking protrusions. That is, the connection between the first connecting structure 111 and the second connecting structure 121 of the other spacer 100, and the connection between the first connecting structure 111 and the fourth connecting structure 141 of the other spacer 100, is an insertion of the locking protrusion into the receiving groove 126. When the first connecting structure 111 is connected to the second connecting structure 121 of the other spacer 100, or when the first connecting structure 111 is connected to the fourth connecting structure 141 of the other spacer 100, the locking protrusion is inserted into the receiving groove 126 to achieve the connection between the first connecting structure 111 and the second connecting structure 121 of the other spacer 100, or the connection between the first connecting structure 111 and the fourth connecting structure 141 of the other spacer 100.

[0057] For example, when the locking strip is inserted into the receiving groove 126, the locking strip and the side wall of the receiving groove 126 can be locked together or there can be a movable gap, which is not specifically limited here. When there is a movable gap between the locking strip and the side wall of the receiving groove 126, the spacer 100 restricts the position of the spacer 100 by the cooperation of the limiting groove 160 and the limiting strip 270 described below, thereby increasing its stability after installation.

[0058] For example, such as Figure 1 As shown, the fifth connecting structure 240 of the storage cavity 210 is a second receiving groove 242 that matches the first connecting structure 111. At least one side of the first connecting structure 111 is provided with a protrusion 112. The protrusion 112 is provided so that when the first connecting structure 111 is connected to the fifth connecting structure 240 of the storage cavity 210, it is a snap-fit ​​connection. That is, among all the partitions installed in the storage cavity 210, some of the partitions 100 are installed in a snap-fit ​​manner. This setting increases the overall stability of each partition 100 after it is installed in the storage cavity 210.

[0059] For example, such as Figure 1 and Figure 2 As shown, the second connecting structure 121 includes a first side 122 and a second side 123, with a receiving groove 126 formed between the first side 122 and the second side 123. The first side 122 includes a plurality of spaced first mating pieces 124, and the second side 123 includes a plurality of spaced second mating pieces 125. The plurality of first mating pieces 124 and the plurality of second mating pieces 125 are staggered. This arrangement facilitates the demolding of the spacer piece 100.

[0060] In some embodiments of this application, the first side 130 is provided with two adjacent and spaced-apart first borders 132. Part of the edges of the first borders 132 extend along the edge of the first side 130, and a retaining strip structure is provided between two adjacent edges of the two first borders 132. The provision of the first borders 132 can increase the stability of the shape of the spacer 100 and reduce deformation and breakage.

[0061] For example, in some embodiments of this application, the second side 140 is provided with two adjacent and spaced second borders 142, three edges of which extend on the edge of the second side 140, and two adjacent edges of the two second borders 142 cooperate to form a receiving groove 126. The provision of the second borders 142 can increase the stability of the shape of the spacer 100 and reduce deformation and breakage.

[0062] This embodiment also provides a storage container, which includes a container body and a storage cavity spacer structure of any of the above-described embodiments. The container body has a storage cavity 210, and the storage cavity 210 has a fifth connecting structure 240 on at least the first side wall 220 and a sixth connecting structure 250 on at least the second side wall 230. The first side wall 220 and the second side wall 230 are opposite side walls of the storage cavity 210, and the distance between the two side walls is configured to allow for the splicing and installation of at least one spacer 100 of the storage cavity spacer structure. That is, the storage cavity 210 has a connecting structure that mates with the spacer 100 on at least one opposite side wall, so that the spacer 100 can be stably installed in the storage cavity 210. Of course, all four side walls of the quadrilateral storage cavity 210 can also be provided with connecting structures, which is not specifically limited here.

[0063] For example, both the fifth connecting structure 240 and the sixth connecting structure 250 include a plurality of spaced-apart second locking protrusions 241 and a second receiving groove 242 formed between any two adjacent second locking protrusions 241. The plurality of second locking protrusions 241 on the first sidewall 220 and the plurality of second locking protrusions 241 on the second sidewall 230 are staggered, thereby enabling the first connecting structure 111 of the spacer 100 to correspondingly engage with the second locking protrusions 241 when the first connecting structure 111 of the spacer 100 is inserted into the second receiving groove 242. That is, the second locking protrusions 241 are configured to receive the second connecting structure 121, and the second receiving groove 242 is configured to receive the first connecting structure 111. When the first connecting structure 111 of the spacer 100 is inserted into the second receiving groove 242, the protrusions 112 of the first connecting structure 111 cooperate with the sidewall of the second receiving groove 242, causing the first connecting structure 111 to be locked in the second receiving groove 242.

[0064] For example, each spacer 100 has a limiting groove 160 on its bottom end face 150 in the height direction, and the limiting groove 160 extends in the length direction of the spacer 100. The bottom wall 260 of the storage cavity 210 has at least one limiting strip 270, wherein at least one limiting strip 270 extends in the length direction of the storage cavity 210, and the limiting strip 270 is configured to cooperate with the limiting groove 160. When multiple spacers 100 are spliced ​​together in the storage cavity 210 along the length direction X, the cooperation between the limiting groove 160 and the limiting strip 270 can reduce the shaking after the multiple spacers 100 are spliced ​​together. Example

[0065] This embodiment provides a mating container body, which is configured to be installed inside a storage container, such as... Figure 3 and Figure 4As shown, the container body includes a container body 200 and a storage cavity spacer structure as described in any of the embodiments in Example 1. The container body 200 has a storage cavity 210. The storage cavity 210 has a fifth connecting structure 240 on at least the first side wall 220 and a sixth connecting structure 250 on at least the second side wall 230. The first side wall 220 and the second side wall 230 are the two opposite side walls of the storage cavity 210, and the distance between the two side walls is configured to allow for the splicing and installation of at least one spacer 100. That is, the storage cavity 210 has a connecting structure that mates with the spacer 100 on at least one opposite side wall, so that the spacer 100 can be stably installed in the storage cavity 210. Of course, all four side walls of the quadrilateral storage cavity 210 can also be provided with connecting structures, which is not specifically limited here. The configuration of the container body 200 enables storage containers without the fifth connecting structure 240 and the sixth connecting structure 250 to also have spatial spacing. That is, the container body 200 with the fifth connecting structure 240 and the sixth connecting structure 250 is installed in the accommodating cavity of the storage container, so that the accommodating cavity of the storage container can also achieve flexible and varied spatial spacing through the spatial spacing of the container body 200.

[0066] The mating container body provided in this application embodiment can be installed inside a storage container, enabling flexible spatial partitioning even in storage containers lacking space separation functionality. The beneficial effects of the storage cavity of the mating container body being flexibly partitioned by spacers are the same as the beneficial effects of the aforementioned storage cavity partitioning structure, and will not be repeated here.

[0067] For example, both the fifth connecting structure 240 and the sixth connecting structure 250 include a plurality of spaced-apart second locking protrusions 241 and a second receiving groove 242 formed between any two adjacent second locking protrusions 241. The plurality of second locking protrusions 241 on the first sidewall 220 and the plurality of second locking protrusions 241 on the second sidewall 230 are staggered, thereby enabling the first connecting structure 111 of the spacer 100 to correspondingly engage with the second locking protrusions 241 when the first connecting structure 111 of the spacer 100 is inserted into the second receiving groove 242. That is, the second locking protrusions 241 are configured to receive the second connecting structure 121, and the second receiving groove 242 is configured to receive the first connecting structure 111. When the first connecting structure 111 of the spacer 100 is inserted into the second receiving groove 242, the protrusions 112 of the first connecting structure 111 cooperate with the sidewall of the second receiving groove 242, causing the first connecting structure 111 to be locked in the second receiving groove 242.

[0068] For example, each spacer 100 has a limiting groove 160 on its bottom end face 150 in the height direction, and the limiting groove 160 extends in the length direction of the spacer 100. The bottom wall 260 of the storage cavity 210 has at least one limiting strip 270, wherein at least one limiting strip 270 extends in the length direction of the storage cavity 210, and the limiting strip 270 is configured to cooperate with the limiting groove 160. When multiple spacers 100 are spliced ​​together in the storage cavity 210 along the length direction X, the cooperation between the limiting groove 160 and the limiting strip 270 can reduce the shaking after the multiple spacers 100 are spliced ​​together.

[0069] This embodiment also provides a storage container, which includes a container body and mating container bodies as described in any of the above-described solutions. The container body has a receiving cavity, and the number of mating container bodies is one or more, with each mating container body installed within the receiving cavity. For example, each mating container body is fitted and snapped into place within the receiving cavity. The storage container's receiving cavity houses mating container bodies capable of flexibly partitioning space, enabling storage containers without spatial partitioning functions to achieve flexible spatial partitioning, thus facilitating use.

[0070] Other embodiments of this application will readily occur to those skilled in the art upon consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of this application that follow the general principles of this application and include common knowledge or customary techniques in the art not disclosed herein. The specification and examples are to be considered exemplary only, and the true scope and spirit of this application are indicated by the following claims.

[0071] It should be understood that this application is not limited to the precise structure described above and shown in the accompanying drawings, and various modifications and changes can be made without departing from its scope. The scope of this application is limited only by the appended claims.

Claims

1. A storage cavity spacer structure, characterized in that, It includes multiple spacers, each of which has a first end face and a second end face in the length direction, and a first side face and a second side face in the thickness direction; The first end face is provided with a first connection structure, which is configured to connect with a fifth connection structure on the side wall of the storage cavity; The second end face is provided with a second connection structure, and the first connection structure is configured to be able to connect with the sixth connection structure of the storage cavity sidewall and to connect with the first connection structure of another spacer. The first side is provided with a third connecting structure, which is configured to connect with the second connecting structure of another spacer. The second side is provided with a fourth connection structure, which is configured to connect with the first connection structure of another spacer.

2. The storage cavity spacer structure according to claim 1, characterized in that, The first and third connecting structures are locking protrusions; the second and fourth connecting structures are receiving grooves that cooperate with the locking protrusions.

3. The storage cavity spacer structure according to claim 2, characterized in that, The first connecting structure has a protrusion on at least one side.

4. The storage cavity spacer structure according to claim 2, characterized in that, The second connection structure includes a first side and a second side, and the receiving groove is formed between the first side and the second side; The first side includes a plurality of spaced first mating pieces, and the second side includes a plurality of spaced second mating pieces, with the plurality of first mating pieces and the plurality of second mating pieces being alternately arranged.

5. The storage cavity spacer structure according to claim 2, characterized in that, The first side has two adjacent and spaced first borders, and part of the edges of the first borders extend on the edge of the first side. The card protrusion structure is provided between the two adjacent edges of the two first borders.

6. The storage cavity spacer structure according to any one of claims 2-5, characterized in that, The second side has two adjacent and spaced second frame borders, three edges of which extend on the edge of the second side, and two adjacent edges of the two second frame borders cooperate to form the receiving groove.

7. A matching container body, characterized in that, The mating container body is configured to be installed inside the storage container, and the mating container body includes a mating container body body and the storage cavity partition structure according to any one of claims 1-6; The container body has a storage cavity, the storage cavity has a fifth connecting structure on at least the first side wall and a sixth connecting structure on at least the second side wall; the first side wall and the second side wall are the two opposite side walls of the storage cavity, and the distance between the two side walls is configured to allow for the splicing and installation of at least one spacer of the storage cavity spacer structure.

8. The mating container body according to claim 7, characterized in that, Both the fifth and sixth connecting structures include a plurality of spaced second protrusions and a second receiving groove formed between any two adjacent second protrusions. The plurality of second protrusions on the first sidewall are staggered with the plurality of second protrusions on the second sidewall. The second protrusions are configured to receive the second connecting structure, and the second receiving groove is configured to receive the first connecting structure.

9. The mating container body according to claim 7, characterized in that, Each spacer in the storage cavity spacer structure has a limiting groove on its bottom end face in the height direction, and the limiting groove extends in the length direction of the spacer. The bottom wall of the storage cavity is provided with at least one limiting strip, wherein at least one of the limiting strips extends in the length direction of the storage cavity, and the limiting strip is configured to cooperate with the limiting groove.

10. A storage container, characterized in that, Includes the container body and the storage cavity spacer structure as described in any one of claims 1-6; The container body has a storage cavity, the storage cavity has at least a fifth connecting structure on the first side wall, and the storage cavity has at least a sixth connecting structure on the second side wall; the first side wall and the second side wall are the two opposite side walls of the storage cavity, and the distance between the two side walls is configured to allow for the splicing and installation of at least one spacer of the storage cavity spacer structure.

11. The storage container according to claim 10, characterized in that, Each of the spacers has a limiting groove on its bottom end face in the height direction, and the limiting groove extends in the length direction of the spacer; The bottom wall of the storage cavity is provided with at least one limiting strip, wherein at least one of the limiting strips extends in the length direction of the storage cavity, and the limiting strip is configured to cooperate with the limiting groove.

12. A storage container, characterized in that, Includes a container body and a mating container body as described in any one of claims 7-9, wherein the container body has a receiving cavity; The number of the mating containers is one or more, and each of the mating containers is installed in the accommodating cavity.