Steel structural frame for office cubicles

The design of sliding plates and rotating grooves allows for flexible adjustment of the angle and length of the steel frame of the office partition, solving the problem of insufficient adaptability of traditional frames in irregular building spaces and improving space utilization and reconfigurability.

CN224412880UActive Publication Date: 2026-06-26NINGBO XINGUANG STEEL STRUCTURE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
NINGBO XINGUANG STEEL STRUCTURE CO LTD
Filing Date
2025-07-25
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

The steel frame structure of traditional office cubicles cannot adapt to the diverse layout needs of modern architectural spaces. Especially in irregularly shaped architectural spaces or when the layout of workstations needs to be dynamically adjusted, the existing rigid connection method limits the reconfigurability and space utilization of the cubicles.

Method used

The design employs a combination of a sliding plate and a rotating groove, which allows for flexible adjustment of the compartment angle. The length is adjusted by a sliding locking mechanism between the insert and the slot, and the angle is locked by the combination of the insert rod and the circular groove, providing dual adjustment functions for both length and angle.

Benefits of technology

Breaking through the limitations of traditional 90-degree right-angle partitions, it meets the needs of irregularly shaped building spaces and diverse office layouts, improves the space utilization and reconfigurability of the partition system, and ensures operational stability and connection solidity.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses an office partition steel structure frame, which comprises a first partition plate, a sliding groove is formed in the right end surface of the first partition plate, a sliding plate is slidably connected in the sliding groove, sliding grooves are symmetrically formed in the sliding groove, sliding plates which are matched with the sliding grooves are symmetrically and fixedly connected to the outer side of the sliding plate, a plurality of insertion grooves are formed in the inner wall of the sliding groove, a cavity is formed in the sliding plate, two sliding rods are symmetrically and slidably connected in the cavity, springs are fixedly connected between the two sliding rods, and moving grooves which are communicated with the cavity are formed in the two opposite sliding plates. The application realizes flexible adjustment of the partition angle, the second partition plate can freely rotate around the shaft rod through the cooperation of the sliding plate and the rotating groove, the limitation of the traditional ninety-degree right-angle partition is broken, the demand of special-shaped building space and diversified office layout is met, and the problem of insufficient adaptability of the existing rigid connection mode is solved.
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Description

Technical Field

[0001] This application relates to the field of office partition frame technology, and more specifically, to a steel structure frame for office partitions. Background Technology

[0002] Office cubicles are modular partitions built in open office spaces using a combination of panels, frames, and other materials. They are used to divide independent work areas and ensure a certain degree of privacy. Generally, office cubicles use steel structure frames.

[0003] In traditional office cubicle designs, frames are typically connected at fixed 90-degree angles. While this standardized configuration facilitates mass production and installation, it struggles to adapt to the diverse layout needs of modern architectural spaces. As office environments evolve towards greater flexibility and human-centered design, the single right-angle cubicle can no longer meet the personalized requirements for space division, functional zoning, and aesthetic design in different scenarios. Especially in irregularly shaped architectural spaces or locations requiring dynamic adjustments to workstation layouts, the existing rigid connection method limits the reconfigurability and space utilization of the cubicles.

[0004] To address the aforementioned issues, this application provides a steel structure frame for office partitions. Utility Model Content

[0005] One objective of this application is to provide a steel structural frame for office partitions, including a first partition. A sliding groove is formed on the right end face of the first partition. A sliding plate is slidably connected inside the sliding groove. Symmetrically arranged sliding channels are formed inside the sliding groove. Sliding plates adapted to the sliding channels are symmetrically fixedly connected to the outer sides of the sliding plates. Rotating grooves are formed on both the upper and lower right sides of the sliding plate. A second partition is rotatably connected inside the two rotating channels. Multiple slots are formed on the inner wall of the sliding channels. A cavity is formed inside the sliding plate. The cavities are symmetrically arranged inside. The sliding connection has two sliding rods, and a spring is fixedly connected between the two sliding rods. Each of the two opposing sliding plates has a moving groove that communicates with the cavity. The left end of each sliding rod is slidably connected inside the moving groove. Two inserts are symmetrically fixedly connected to the left end of each sliding rod. The sliding plates have symmetrically opened grooves that communicate with the cavity. A sliding plate is slidably connected inside the groove. An insert is fixedly connected to the sliding plate. Circular grooves are opened on opposite sides of the upper and lower ends of the second partition. A first unlocking component and a second unlocking component are provided on the surface of the sliding plate.

[0006] Furthermore, the right end of the sliding rod is fixedly connected to the slide plate, and the end of the insert rod away from the slide plate passes through the right inner cavity of the sliding plate and extends into the interior of the circular groove.

[0007] Furthermore, the first unlocking component includes a first sliding hole and a first carrying plate. The surface of the sliding plate is symmetrically provided with a first sliding hole that communicates with the cavity. The first carrying plate is slidably connected inside the first sliding hole, and the first carrying plate is fixedly connected to the surface of the sliding rod.

[0008] Furthermore, the second unlocking component includes a second sliding hole and a second carrying plate. The surface of the sliding plate is symmetrically provided with a second sliding hole that communicates with the cavity. The second carrying plate is slidably connected inside the second sliding hole, and the second carrying plate is fixedly connected to the surface of the sliding rod.

[0009] Furthermore, the width of the second sliding hole is smaller than the width of the first sliding hole, the distance between the first carrying plate and the inner wall of the first sliding hole is equal to the depth of the slot, and the distance between the second carrying plate and the inner wall of the second sliding hole is equal to the depth of the circular groove.

[0010] Furthermore, a shaft is fixedly connected to the inner wall of the rotating groove, and circular grooves adapted to the shaft are symmetrically opened on the second partition plate.

[0011] Furthermore, the sliding rod is configured in a "U" shape, and the length of the sliding plate is equal to the length of the sliding groove.

[0012] The beneficial effects of this application are:

[0013] 1. This application enables flexible adjustment of the partition angle. Through the cooperative design of the sliding plate and the rotating groove, the second partition can rotate freely around the axis, breaking through the limitation of traditional 90-degree right-angle partitions, meeting the needs of irregular building spaces and diverse office layouts, and solving the problem of insufficient adaptability of existing rigid connection methods. It provides dual adjustment functions of length and angle. Utilizing the sliding locking mechanism of the plug and slot, the extension length of the first partition and the sliding plate can be adjusted. At the same time, the angle is locked through the cooperation of the plug and the circular groove, which significantly improves the space utilization and reconfigurability of the partition system and adapts to the needs of dynamic workstation layouts.

[0014] 2. The hierarchical unlocking structure ensures operational stability. The width difference between the first and second sliding holes prevents length and angle adjustments from interfering with each other. The feature that the slot depth is greater than the circular groove depth ensures that the length lock is always effective when adjusting the angle, avoiding structural loosening caused by misoperation. Attached Figure Description

[0015] The accompanying drawings are provided to further understand this application and form part of the specification. They are used together with the embodiments of this application to explain this application and do not constitute a limitation thereof.

[0016] In the attached diagram:

[0017] Figure 1This is a schematic diagram of the overall structure of this application;

[0018] Figure 2 This is a partial structural diagram of this application;

[0019] Figure 3 This is a partial structural cross-sectional view of this application;

[0020] Figure 4 This is a schematic diagram of the sliding rod structure of this application;

[0021] Figure 5 For the purposes of this application Figure 1 Enlarged schematic diagram of the middle section structure;

[0022] Figure 6 For the purposes of this application Figure 4 Enlarged schematic diagram of the middle section structure.

[0023] Explanation of the labels in the diagram:

[0024] 1. First partition; 2. Second partition; 201. Circular groove; 202. Slide plate; 3. Sliding groove; 4. Sliding plate; 5. Rotating groove; 6. Sliding groove; 7. Sliding plate; 8. First carrying plate; 9. Second sliding hole; 10. First sliding hole; 11. Second carrying plate; 12. Slot; 13. Insert block; 14. Insert rod; 15. Cavity; 16. Sliding rod; 17. Spring; 18. Sliding groove; 19. Moving groove. Detailed Implementation

[0025] The technical solutions in the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of this application without creative effort are within the scope of protection of this application.

[0026] In the description of this application, it should be noted that the terms "upper," "lower," "inner," "outer," "top / bottom," etc., indicating the orientation or positional relationship are based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing this application and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this application. Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance.

[0027] In the description of this application, it should be noted that, unless otherwise expressly specified and limited, the terms "installed," "equipped with," "sleeved / connected," "connected," etc., should be interpreted broadly. For example, "connection" can be a fixed connection, a detachable connection, or an integral connection; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium; it can be a connection within two components. Those skilled in the art can understand the specific meaning of the above terms in this application based on the specific circumstances.

[0028] Example:

[0029] Please see Figure 1 , Figure 2 , Figure 3 , Figure 4 , Figure 5 and Figure 6 This application discloses a steel structure frame for office partitions, including a first partition 1. A sliding groove 3 is formed on the right end face of the first partition 1. A sliding plate 4 is slidably connected inside the sliding groove 3. A sliding channel 6 is symmetrically formed inside the sliding groove 3. Sliding plates 7, adapted to the sliding channel 6, are symmetrically fixedly connected to the outer side of the sliding plate 4. Rotating grooves 5 are formed on both the upper and lower right sides of the sliding plate 4. A second partition 2 is rotatably connected inside the two rotating grooves 5. Multiple slots 12 are formed on the inner wall of the sliding channel 6. A cavity 15 is formed inside the sliding plate 4. Two sliding rods are symmetrically slidably connected inside the cavity 15. 16. A spring 17 is fixedly connected between the two sliding rods 16. Each of the two opposing sliding plates 7 is provided with a moving groove 19 that communicates with the cavity 15. The left end of the sliding rod 16 is slidably connected to the inside of the moving groove 19. Two insert blocks 13 are symmetrically fixedly connected to the left end of the sliding rod 16. The sliding plate 4 is symmetrically provided with a sliding groove 18 that communicates with the cavity 15. A sliding plate 202 is slidably connected inside the sliding groove 18. An insert rod 14 is fixedly connected to the sliding plate 202. Circular grooves 201 are provided on opposite sides of the upper and lower ends of the second partition 2. The surface of the sliding plate 4 is provided with a first unlocking component and a second unlocking component.

[0030] Please see Figure 1 , Figure 2 , Figure 3 and Figure 4The right end of the sliding rod 16 is fixedly connected to the slide plate 202. The end of the insert rod 14 away from the slide plate 202 passes through the right inner cavity of the sliding plate 4 and extends into the interior of the circular groove 201. The first unlocking component includes a first sliding hole 10 and a first carrying plate 8. The surface of the sliding plate 4 is symmetrically provided with a first sliding hole 10 communicating with the cavity 15. The first carrying plate 8 is slidably connected inside the first sliding hole 10. The first carrying plate 8 is fixedly connected to the surface of the sliding rod 16. The second unlocking component includes a second sliding hole 9 and a second carrying plate 11. The surface of the sliding plate 4 is symmetrically provided with a second sliding hole 9 communicating with the cavity 15. The second carrying plate 11 is slidably connected inside the second sliding hole 9. The second carrying plate 11 is fixedly connected to the surface of the sliding rod 16. The width of the second sliding hole 9 is smaller than the width of the first sliding hole 10. The depth of the slot 12 is greater than the depth of the circular groove 201. The distance between the lifting plate 8 and the inner wall of the first sliding hole 10 is equal to the depth of the slot 12. The distance between the second lifting plate 11 and the inner wall of the second sliding hole 9 is equal to the depth of the circular groove 201. First, the two first lifting plates 8 are moved relative to each other. The movement of the first lifting plates 8 causes the sliding rod 16 inside the cavity 15 to move. The movement of the sliding rod 16 causes the insert block 13 to move. When the two first lifting plates 8 move relative to each other and contact the inner walls of the two first sliding holes 10 respectively, the insert block 13 moves out of the slot 12, thereby releasing the connection between the first partition 1 and the sliding plate 4. Then, the sliding plate 4 is moved to slide inside the sliding groove 3, so that the total length between the first partition 1 and the sliding plate 4 can be adjusted, thereby facilitating the adjustment of the position of the second partition 2 and the adjustment of the position of the turning point of the second partition 2 relative to the sliding plate 4, thus improving the practicality of the device.

[0031] The two second carrying plates 11 are moved relative to each other, causing the two sliding rods 16 to drive the two sliding plates 202 to move respectively. The movement of the sliding plates 202 drives the insertion rod 14 to move. When the two second carrying plates 11 move relative to each other and contact the inner walls of the two second sliding holes 9 respectively, the insertion rod 14 moves out of the inside of the circular groove 201, thereby releasing the restriction on the second partition 2. Since the depth of the slot 12 is greater than the depth of the circular groove 201, the insertion block 13 will not move out of the inside of the slot 12, thus ensuring the stability of the connection between the sliding plate 4 and the first partition 1. Then, the second partition 2 is rotated, which facilitates the adjustment of the angle between the first partition 1 and the second partition 2.

[0032] Please see Figure 3 A shaft is fixedly connected to the inner wall of the rotating groove 5. The second partition 2 is rotatably connected to the outside of the sliding plate 4 through the cooperation of the shaft and the circular groove, which facilitates the rotation adjustment of the second partition 2. The second partition 2 is symmetrically provided with circular grooves that are adapted to the shaft. The sliding rod 16 is set in a "U" shape. The length of the sliding plate 7 is equal to the length of the sliding groove 6.

[0033] The implementation principle of this application embodiment is as follows: First, when it is necessary to adjust the total length between the first partition 1 and the sliding plate 4, the operator simultaneously presses the two first lifting plates 8 inward, causing them to slide relative to each other along the first sliding hole 10. The first lifting plates 8 drive the sliding rod 16 to move within the cavity 15 and compress the spring 17. The movement of the sliding rod 16 causes the insert 13 fixed at its left end to exit from the slot 12. At this time, the limit of the sliding plate 7 and the sliding groove 6 is released, and the sliding plate 4 can be pushed to slide horizontally along the sliding groove 3 to change the extension length, thereby facilitating the adjustment of the position of the second partition 2. After the adjustment is in place, the first lifting plates 8 are released, the spring 17 rebounds and pushes the sliding rod 16 to reset, and the insert 13 is re-engaged into the slot 12 at the corresponding position to achieve fixation.

[0034] When it is necessary to adjust the angle between the first partition 1 and the second partition 2, press the two second lifting plates 11 inward simultaneously to move them along the second sliding hole 9. The second lifting plates 11 drive the sliding rod 16 to make the slide plate 202 slide along the sliding groove 18. At this time, the insertion rod 14 exits from the circular groove 201, but the insertion block 13 remains locked. Then, the second partition 2 can be rotated around the shaft in the rotating groove 5 to the required angle. After releasing the second lifting plates 11, the spring 17 pushes the insertion rod 14 to re-insert into the circular groove 201 to complete the fixation. The full cooperation between the sliding plate 7 and the sliding groove 6 ensures the stability of the sliding plate 4. The shaft structure of the rotating groove 5 and the circular groove ensures the smooth rotation of the second partition 2. The width difference design between the first sliding hole 10 and the second sliding hole 9 enables graded unlocking. The feature that the depth of the slot 12 is greater than the depth of the circular groove 201 ensures that the connection stability between the first partition 1 and the sliding plate 4 is not disturbed when adjusting the angle.

[0035] The above description is merely a preferred embodiment of this application, but the scope of protection of this application is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in this application, based on the technical solution and application concept of this application, should be included within the scope of protection of this application.

Claims

1. A steel structure frame for office partitions, comprising a first partition (1), characterized in that: A sliding groove (3) is provided on the right end face of the first partition (1). A sliding plate (4) is slidably connected inside the sliding groove (3). A sliding groove (6) is symmetrically provided inside the sliding groove (3). A sliding plate (7) that matches the sliding groove (6) is symmetrically fixedly connected to the outside of the sliding plate (4). Rotating grooves (5) are provided on both the upper and lower sides of the right end of the sliding plate (4). A second partition (2) is rotatably connected inside the two rotating grooves (5). A plurality of slots (12) are provided on the inner wall of the sliding groove (6). A cavity (15) is provided inside the sliding plate (4). Two sliding rods (16) are symmetrically slidably connected inside the cavity (15). A spring (17) is fixedly connected between the two sliding plates (7). Each of the two sliding plates (7) is provided with a moving groove (19) that communicates with the cavity (15). The left end of the sliding rod (16) is slidably connected to the inside of the moving groove (19). Two inserts (13) are symmetrically fixedly connected to the left end of the sliding rod (16). The sliding plate (4) is symmetrically provided with a sliding groove (18) that communicates with the cavity (15). A sliding plate (202) is slidably connected inside the sliding groove (18). An insert rod (14) is fixedly connected to the sliding plate (202). Circular grooves (201) are provided on opposite sides of the upper and lower ends of the second partition (2). The surface of the sliding plate (4) is provided with a first unlocking component and a second unlocking component.

2. The steel structure frame for office partitions according to claim 1, characterized in that: The right end of the sliding rod (16) is fixedly connected to the slide plate (202), and the end of the insert rod (14) away from the slide plate (202) passes through the right inner cavity of the sliding plate (4) and extends into the interior of the circular groove (201).

3. The steel structure frame for office partitions according to claim 1, characterized in that: The first unlocking component includes a first sliding hole (10) and a first carrying plate (8). The surface of the sliding plate (4) is symmetrically provided with a first sliding hole (10) that communicates with the cavity (15). The first carrying plate (8) is slidably connected inside the first sliding hole (10). The first carrying plate (8) is fixedly connected to the surface of the sliding rod (16).

4. The steel structure frame for office partitions according to claim 3, characterized in that: The second unlocking component includes a second sliding hole (9) and a second carrying plate (11). The surface of the sliding plate (4) is symmetrically provided with a second sliding hole (9) that communicates with the cavity (15). The second carrying plate (11) is slidably connected inside the second sliding hole (9). The second carrying plate (11) is fixedly connected to the surface of the sliding rod (16).

5. A steel structure frame for office partitions according to claim 4, characterized in that: The width of the second sliding hole (9) is smaller than the width of the first sliding hole (10). The distance between the first carrying plate (8) and the inner wall of the first sliding hole (10) is equal to the depth of the slot (12). The distance between the second carrying plate (11) and the inner wall of the second sliding hole (9) is equal to the depth of the circular groove (201).

6. The steel structure frame for office partitions according to claim 1, characterized in that: The inner wall of the rotating groove (5) is fixedly connected with a shaft, and the second partition (2) is symmetrically provided with circular grooves that are adapted to the shaft.

7. A steel structure frame for office partitions according to claim 1, characterized in that: The sliding rod (16) is arranged in a "U" shape, and the length of the sliding plate (7) is equal to the length of the sliding groove (6).