A composite container rack with a shelf height adjustment mechanism
By setting up partitions and support holes inside the cabinet, combined with drive components and guide slots, the partitions can be quickly adjusted, solving the problem of the complexity of existing cabinet height design, improving space utilization and equipment placement stability, and meeting the efficient management needs of modern data centers.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WANMA TECH CO LTD
- Filing Date
- 2025-06-07
- Publication Date
- 2026-06-30
Smart Images

Figure CN224439412U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of computer room equipment storage technology, and in particular to a comprehensive container rack with a height adjustment mechanism. Background Technology
[0002] A server rack is a freestanding or self-supporting enclosure used to house electrical or electronic equipment. It is an indispensable component of electrical equipment, serving as a carrier for electrical control devices. Generally made of cold-rolled steel or alloys, server racks provide protection against water, dust, and electromagnetic interference for the stored equipment.
[0003] Currently, with the rapid development of communication technology, the types and quantities of equipment in data centers are constantly increasing, especially the storage needs for small devices such as optical modems. To accommodate the storage needs of devices of different sizes, common solutions on the market include fixed-height designs and some adjustable-height designs. Fixed-height designs achieve layered storage of equipment through pre-set partition positions, offering simple operation and a stable structure; while adjustable-height designs adjust partition positions through bolt connections, sliding rails, or other mechanical structures to meet diverse storage requirements. In addition, some server racks adopt a modular design concept, allowing for flexible space layout by replacing or adjusting internal components.
[0004] However, existing adjustable height designs generally suffer from complex adjustment mechanisms and inconvenient operation. For example, bolted connections require frequent disassembly and assembly, increasing maintenance costs; while slide rail connections may experience decreased precision due to component wear, affecting long-term performance. These issues not only reduce cabinet space utilization but can also lead to disorganized equipment placement and even affect heat dissipation and maintenance efficiency, failing to fully meet the demands of modern data centers for efficient space management. Utility Model Content
[0005] In view of the deficiencies in the existing technology, the technical problem solved by this utility model is: how to improve the utilization rate of the storage space of the server rack.
[0006] To achieve the above objectives, the present invention provides a comprehensive container rack with a layer height adjustment mechanism, comprising:
[0007] The main body of the server rack has several partitions inside.
[0008] The partition support assembly is vertically installed on the main body of the cabinet, and multiple first support holes are opened on the partition support assembly along its setting direction;
[0009] A partition mounting assembly is disposed at the bottom of the partition. The partition mounting assembly includes a drive assembly and a first mounting post. The drive assembly is used to drive the first mounting post to move so as to achieve assembly and separation between the first mounting post and the first support hole.
[0010] By adopting the above technical solution, several partitions are set inside the main body of the cabinet. Combined with multiple first support holes on the partition support assembly, multiple installation positions are provided for the partitions, thereby meeting the storage needs of equipment of different sizes. The drive component in the partition installation assembly drives the first mounting column to move, realizing the rapid assembly and separation between the first mounting column and the first support hole. The operation is simple, improving the space utilization of the cabinet and the flexibility of equipment placement.
[0011] In one embodiment, the partition mounting assembly further includes a mounting body, a driving assembly is mounted inside the mounting body, the mounting body has a plurality of first holes, and a first mounting post is movably inserted through the first holes.
[0012] By adopting the above technical solution, the installation body provides a stable installation space for the drive components, while the design of the first hole provides guidance for the movement of the first hole.
[0013] In one embodiment, the driving assembly includes a first driving plate, a second driving plate, a first driving rod, a second driving rod, and a spring-loaded assembly. The first driving plate is movably disposed in a first guide groove on the mounting body, and the second driving plate is movably disposed in a second guide groove on the mounting body. A plurality of first driving rods are disposed on the side of the first driving plate closest to the second driving plate, and a plurality of first mounting posts are disposed on the side of the first driving plate furthest from the second driving plate. A plurality of second driving rods are disposed on the side of the second driving plate closest to the first driving plate, and a plurality of first mounting posts are disposed on the side of the second driving plate furthest from the first driving plate. The first driving rods and second driving rods correspond one-to-one, and a spring-loaded assembly is disposed between the corresponding first driving rods and second driving rods to enable the spring-loaded assembly to drive the first driving plate and the second driving plate to move.
[0014] By adopting the above technical solution, the first drive plate and the second drive plate are respectively set in different guide slots of the mounting body, enabling relative movement. The first drive plate and the second drive plate are respectively provided with a first drive rod and a second drive rod, and the first drive rod and the second drive rod are connected by a spring-loaded assembly. This structural design makes the installation and disassembly of the partition more convenient. Users can quickly assemble and separate the first mounting column from the first support hole on the partition support assembly by operating the drive assembly, thereby flexibly adjusting the height position of the partition and improving the utilization rate of the internal space of the cabinet. At the same time, the spring-loaded assembly effectively improves the stability of operation and avoids the unexpected movement of the first drive plate and the second drive plate due to external forces.
[0015] In one embodiment, a second mounting post is provided on the first drive plate. The direction of the second mounting post is perpendicular to the direction of movement of the first drive plate. The second mounting post includes a support post, a spring, and a telescopic post. One end of the support post is fixedly mounted on the first drive plate, and one end of the telescopic post is connected to the end of the support post away from the first drive plate via the spring. A plurality of second holes are provided on the mounting body to allow the telescopic post to abut against the inner wall of the mounting body or to be movably inserted into the interior of the second holes. A plurality of second support holes are provided on the partition support assembly along its direction to allow for the assembly and separation of the telescopic post and the second support holes.
[0016] By adopting the above technical solution, the assembly and separation between the telescopic column and the second support hole are added to the above installation structure, which further enhances the stability of the installation.
[0017] In one embodiment, a first baffle is fixedly sleeved on the first drive rod, and a second baffle is fixedly sleeved on the second drive rod. One end of the rebound assembly abuts against the first baffle, and the other end abuts against the second baffle.
[0018] By adopting the above technical solution, the two ends of the rebound assembly abut against the first baffle and the second baffle respectively, ensuring that the rebound assembly can accurately and reliably transmit the elastic force, thereby realizing the relative movement between the first drive plate and the second drive plate.
[0019] In one embodiment, the rebound assembly is a spring, with one end of the spring sleeved on the first drive rod and the other end sleeved on the second drive rod.
[0020] By adopting the above technical solution, bending of the spring component during compression and rebound is avoided, and the spring component can be guided by the first drive rod and the second drive rod.
[0021] In one embodiment, both the first drive plate and the second drive plate are provided with a toggle plate at their bottoms, and the toggle plate is located at the bottom of the mounting body.
[0022] By adopting the above technical solution, it is easy to drive the first drive plate and the second drive plate closer together, and drive the first mounting post to separate from the first support hole, thereby adjusting the height of the partition.
[0023] In one embodiment, the outer wall of the mounting body is provided with a guide groove, and the cabinet body is provided with a guide rail, with the guide groove movably disposed on the guide rail.
[0024] By adopting the above technical solution, the height adjustment of the partition is guided and positioned, ensuring that after the partition is adjusted, the first mounting column and the first support hole can be directly assembled without secondary positioning.
[0025] In one embodiment, the partition includes a placement plate and a fixing plate, the fixing plate having a fixing hole, which is fixedly connected to the first support hole by a bolt assembly.
[0026] By adopting the above technical solutions, the stability and strength of the partition installation are further enhanced, thereby supporting heavier equipment.
[0027] In one embodiment, an L-shaped connecting plate is provided at the bottom of the partition, and the partition mounting assembly is mounted on the L-shaped connecting plate.
[0028] By adopting the above technical solution, it is convenient to assemble and disassemble the partition mounting components.
[0029] In summary, this utility model has at least one of the following beneficial technical effects:
[0030] 1. By setting several partitions inside the main body of the cabinet, combined with multiple first support holes on the partition support assembly, multiple installation positions are provided for the partitions, thereby meeting the storage needs of equipment of different sizes; the drive component in the partition installation assembly drives the first mounting column to move, realizing the rapid assembly and separation between the first mounting column and the first support hole, which is easy to operate and improves the space utilization of the cabinet.
[0031] 2. Through the specific design of the drive components, the movement of the first drive plate and the second drive plate can simultaneously drive the first mounting column to assemble with the first support hole and the telescopic column to assemble with the second support hole, thereby improving the stability of the partition installation. Attached Figure Description
[0032] Figure 1 This is a schematic diagram of the structure of the integrated container rack with a layer height adjustment mechanism according to an embodiment of the present utility model;
[0033] Figure 2 for Figure 1 Enlarged view of part A;
[0034] Figure 3 This is a schematic diagram of the partition mounting assembly according to an embodiment of the present utility model;
[0035] Figure 4 for Figure 3 The front view;
[0036] Figure 5 This is a schematic diagram of the partition structure in an embodiment of the present utility model.
[0037] In the diagram: 1-Rack body, 2-Block, 201-Placement plate, 202-Fixing plate, 203-Fixing hole, 204-L-shaped connecting plate, 3-Block mounting assembly, 301-Mounting body, 302-First mounting post, 303-First hole, 304-First drive plate, 305-First guide groove, 306-Second drive plate, 307-Second guide groove, 308-First drive rod, 309-Second drive rod, 3010-Second mounting post, 3011-Support post, 3012-Telescopic post, 3013-First baffle, 3014-Second baffle, 3015-Rebound assembly, 3016-Guide groove, 3017-Second hole, 3018-Toggle plate, 4-First support hole, 5-Second support hole, 6-Guide rail. Detailed Implementation
[0038] The embodiments of this utility model will be further described in detail below with reference to the accompanying drawings.
[0039] The integrated container rack with a layer height adjustment mechanism in this embodiment of the utility model is shown in [reference]. Figure 1-3 As shown, the integrated rack with a height adjustment mechanism includes a cabinet body 1, inside which are arranged several partitions 2; a partition 2 support assembly, which is vertically installed on the cabinet body 1, and a plurality of first support holes 4 are opened on the partition 2 support assembly along its setting direction; a partition mounting assembly 3, which is arranged at the bottom of the partition 2, and the partition mounting assembly 3 includes a drive assembly and a first mounting post 302. The drive assembly is used to drive the first mounting post 302 to move, so as to realize the assembly and separation between the first mounting post 302 and the first support hole 4.
[0040] Therefore, this utility model provides several partitions 2 inside the main body 1 of the cabinet, and with multiple first support holes 4 on the partition 2 support components, it offers multiple installation options for the partitions 2. The partitions 2 divide the cabinet space into spaces of different sizes, thus meeting the storage needs of equipment of different sizes. The drive component in the partition mounting assembly 3 drives the first mounting post 302 to move, enabling rapid assembly and separation between the first mounting post 302 and the first support holes 4. This simple operation improves the space utilization rate of the cabinet.
[0041] Preferred, see Figure 3 As shown, a specific structure of a partition mounting assembly 3 is provided:
[0042] The partition mounting assembly 3 also includes a mounting body 301, a drive assembly is installed inside the mounting body 301, the mounting body 301 has a plurality of first holes 303, and the first mounting post 302 is movably inserted through the first holes 303.
[0043] Specifically, the mounting body 301 provides a placement structure for the drive component to avoid collisions between the drive component and other structures, which could damage the drive component. The mounting body 301 has multiple first holes 303 to guide the first mounting post 302, and the first mounting post 302 does not need to be pre-positioned when assembled with the first support hole 4, thus improving the efficiency of the partition 2 adjustment.
[0044] Further, see Figure 3 As shown, a specific structure of a driver component is provided:
[0045] The drive assembly includes a first drive plate 304, a second drive plate 306, a first drive rod 308, a second drive rod 309, and a spring-loaded assembly 3015. The first drive plate 304 is movably disposed in a first guide groove 305 opened on the mounting body 301, and the second drive plate 306 is movably disposed in a second guide groove 307 opened on the mounting body 301. A plurality of first drive rods 308 are disposed on the side of the first drive plate 304 near the second drive plate 306, and the side of the first drive plate 304 away from the second drive plate 306... A plurality of first mounting posts 302 are provided. A plurality of second driving rods 309 are provided on the side of the second driving plate 306 close to the first driving plate 304, and a plurality of first mounting posts 302 are provided on the side of the second driving plate 306 away from the first driving plate 304. The first driving rods 308 and the second driving rods 309 correspond one to one. A spring-loaded assembly 3015 is provided between the corresponding first driving rods 308 and the second driving rods 309 so as to realize that the spring-loaded assembly 3015 drives the first driving plate 304 and the second driving plate 306 to move.
[0046] Specifically, the first drive plate 304 and the second drive plate 306 are respectively disposed in different guide slots 3016 of the mounting body 301, enabling relative movement; the first drive plate 304 and the second drive plate 306 are respectively provided with a first drive rod 308 and a second drive rod 309, and the first drive rod 308 and the second drive rod 309 are connected by a spring-loaded assembly 3015. This structural design makes the installation and disassembly of the partition 2 more convenient. Users can quickly assemble and separate the first mounting post 302 from the first support hole 4 on the partition 2 support assembly by operating the drive assembly, thereby flexibly adjusting the height position of the partition 2 and improving the utilization rate of the internal space of the cabinet; at the same time, the setting of the spring-loaded assembly 3015 effectively improves the stability of operation and avoids the unexpected movement of the first drive plate 304 and the second drive plate 306 due to external forces.
[0047] Preferably, a second mounting post 3010 is provided on the first drive plate 304. The setting direction of the second mounting post 3010 is perpendicular to the moving direction of the first drive plate 304. The second mounting post 3010 includes a support post 3011, a spring, and a telescopic post 3012. One end of the support post 3011 is fixedly set on the first drive plate 304. One end of the telescopic post 3012 is connected to the end of the support post 3011 away from the first drive plate 304 through the spring. A plurality of second holes 3017 are provided on the mounting body 301 to allow the telescopic post 3012 to abut against the inner wall of the mounting body 301 or to be movably inserted into the interior of the second holes 3017. A plurality of second support holes 5 are provided on the partition plate 2 support assembly along its setting direction to allow the telescopic post 3012 to be assembled and separated from the second support holes 5.
[0048] Specifically, while the first drive plate 304 moves within the first guide groove 305 to move the first mounting post 302, a second mounting post 3010 is provided on the first drive plate 304. The direction of the second mounting post 3010 is perpendicular to the direction of movement of the first drive plate 304. Therefore, when the first mounting post 302 moves telescopically, the second mounting post 3010 moves laterally. A second hole 3017 is provided at a preset position on the side of the mounting body 301 parallel to the direction of movement of the first drive plate 304. When the second mounting post 3010 has not moved to the preset position, the support post 3011 and the telescopic... The column 3012 compresses the spring, and the end of the support column 3011 away from the spring abuts against the inner wall of the mounting body 301 and moves relative to it. When the second mounting column 3010 moves to the preset position, the spring's rebound force pushes the support column 3011 out of the second hole 3017 to achieve the assembly between the telescopic column 3012 and the second support hole 5. When it is necessary to separate the telescopic column 3012 from the second support hole 5, the telescopic column 3012 can simply be retracted into the interior of the mounting body 301. This increases the assembly and separation between the telescopic column 3012 and the second support hole 5, further enhancing the stability of the installation.
[0049] Furthermore, similarly, the second mounting post 3010 can also be installed on the second drive board 306 according to the above design.
[0050] Preferred, see Figure 3 As shown, a first baffle 3013 is fixedly sleeved on the first drive rod 308, and a second baffle 3014 is fixedly sleeved on the second drive rod 309. One end of the rebound assembly 3015 abuts against the first baffle 3013, and the other end abuts against the second baffle 3014.
[0051] Specifically, the two ends of the rebound assembly 3015 abut against the first baffle 3013 and the second baffle 3014 respectively, ensuring that the rebound assembly 3015 can accurately and reliably transmit the elastic force, thereby realizing the relative movement between the first drive plate 304 and the second drive plate 306.
[0052] Furthermore, the rebound assembly 3015 is a spring, with one end of the spring sleeved on the first drive rod 308 and the other end sleeved on the second drive rod 309.
[0053] Specifically, the spring between the first drive rod 308 and the second drive rod 309 is always in a compressed state, and the two ends of the spring abut against the first baffle 3013 and the second baffle 3014 respectively. The first drive rod 308 and the second drive rod 309 can guide the spring to prevent it from bending during compression and rebound.
[0054] Preferred, see Figure 4 As shown, both the bottom of the first drive plate 304 and the second drive plate 306 are provided with a toggle plate 3018, and the toggle plate 3018 is located at the bottom of the mounting body 301.
[0055] Specifically, when it is necessary to adjust the partition 2, the first drive plate 304 and the second drive plate 306 are brought closer together by the toggle plate 3018 so that the first mounting post 302 can be pulled out from the first support hole 4, thereby adjusting the height of the partition 2.
[0056] Preferred, see Figure 2 , 3 As shown, the outer wall of the mounting body 301 is provided with a guide groove 3016, and the cabinet body 1 is provided with a guide rail 6, with the guide groove 3016 movably mounted on the guide rail 6.
[0057] Specifically, during the adjustment of the partition 2, the guide groove 3016 moves along the guide rail 6 to guide the height adjustment of the partition 2 and also plays a positioning role, ensuring that after the partition 2 is adjusted, the first mounting post 302 and the first support hole 4 can be directly assembled without secondary positioning.
[0058] Preferred, see Figure 5 As shown, the partition 2 includes a placement plate 201 and a fixing plate 202. The fixing plate 202 has a fixing hole 203, which is fixedly connected to the first support hole 4 by a bolt assembly.
[0059] Specifically, after the partition 2 is adjusted to the preset height, it is simultaneously bolted to the fixing hole 203 and the first support hole 4 to further enhance the stability and strength of the partition 2 installation, thereby supporting heavier equipment.
[0060] Preferred, see Figure 5As shown, an L-shaped connecting plate 204 is provided at the bottom of the partition 2, and the partition mounting assembly 3 is mounted on the L-shaped connecting plate 204.
[0061] Specifically, two L-shaped connecting plates 204 are set on the parallel sides of the partition 2. The partition mounting assembly 3 is inserted into the bottom of the partition 2 from one end. The partition mounting assembly 3 is mounted on the L-shaped connecting plates 204, which facilitates the assembly and disassembly of the partition mounting assembly 3.
[0062] The above description is merely a specific embodiment of this application, enabling those skilled in the art to understand or implement this application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of this application. Therefore, this application is not to be limited to the embodiments shown herein, but is to be accorded the widest scope consistent with the principles and novel features claimed herein.
Claims
1. A modular container rack with a layer height adjustment mechanism, characterized in that, It includes: The main body of the cabinet (1) has several partitions (2) inside. The partition (2) support assembly is vertically installed on the cabinet body (1), and multiple first support holes (4) are provided on the partition (2) support assembly along its setting direction. The partition mounting assembly (3) is located at the bottom of the partition (2). The partition mounting assembly (3) includes a drive assembly and a first mounting post (302). The drive assembly is used to drive the first mounting post (302) to move so as to achieve the assembly and separation between the first mounting post (302) and the first support hole (4).
2. The integrated container rack with a layer height adjustment mechanism as described in claim 1, characterized in that: The partition mounting assembly (3) also includes a mounting body (301), a drive assembly is installed inside the mounting body (301), the mounting body (301) has a plurality of first holes (303), and a first mounting post (302) is movably inserted inside the first holes (303).
3. The integrated container rack with a layer height adjustment mechanism as described in claim 2, characterized in that: The driving assembly includes a first driving plate (304), a second driving plate (306), a first driving rod (308), a second driving rod (309), and a spring-loaded assembly (3015). The first driving plate (304) is movably disposed in a first guide groove (305) opened on the mounting body (301), and the second driving plate (306) is movably disposed in a second guide groove (307) opened on the mounting body (301). A plurality of first driving rods (308) are disposed on the side of the first driving plate (304) near the second driving plate (306), and the first driving plate (304) away from the second driving plate (306) has a plurality of first driving rods (308). A plurality of first mounting posts (302) are provided on one side, and a plurality of second driving rods (309) are provided on the side of the second driving plate (306) close to the first driving plate (304), and a plurality of first mounting posts (302) are provided on the side of the second driving plate (306) away from the first driving plate (304); the first driving rods (308) and the second driving rods (309) correspond one to one, and a spring-loaded assembly (3015) is provided between the corresponding first driving rods (308) and the second driving rods (309) so as to realize that the spring-loaded assembly (3015) drives the first driving plate (304) and the second driving plate (306) to move.
4. The integrated container rack with a layer height adjustment mechanism as described in claim 3, characterized in that: The first drive plate (304) is provided with a second mounting post (3010). The setting direction of the second mounting post (3010) is perpendicular to the moving direction of the first drive plate (304). The second mounting post (3010) includes a support post (3011), a spring and a telescopic post (3012). One end of the support post (3011) is fixedly set on the first drive plate (304). One end of the telescopic post (3012) is connected to the end of the support post (3011) away from the first drive plate (304) through the spring. The mounting body (301) is provided with a plurality of second holes (3017) so that the telescopic post (3012) abuts against the inner wall of the mounting body (301) or is movably inserted into the interior of the second holes (3017). The partition (2) support assembly is provided with a plurality of second support holes (5) along its setting direction so as to realize the assembly and separation between the telescopic post (3012) and the second support holes (5).
5. The integrated container rack with a layer height adjustment mechanism as described in claim 3, characterized in that: A first baffle (3013) is fixedly sleeved on the first drive rod (308), and a second baffle (3014) is fixedly sleeved on the second drive rod (309). One end of the spring-loaded assembly (3015) abuts against the first baffle (3013), and the other end abuts against the second baffle (3014).
6. The integrated container rack with a layer height adjustment mechanism as described in claim 5, characterized in that: The rebound assembly (3015) is a spring, with one end of the spring sleeved on the first drive rod (308) and the other end sleeved on the second drive rod (309).
7. The integrated container rack with a layer height adjustment mechanism as described in claim 3, characterized in that: Both the first drive plate (304) and the second drive plate (306) are provided with a toggle plate (3018) at the bottom, and the toggle plate (3018) is located at the bottom of the mounting body (301).
8. The integrated container rack with a layer height adjustment mechanism as described in claim 2, characterized in that: The outer wall of the installation body (301) is provided with a guide groove (3016), and a guide rail (6) is provided on the cabinet body (1). The guide groove (3016) is movably disposed on the guide rail (6).
9. The integrated container rack with a layer height adjustment mechanism as described in claim 1, characterized in that: The partition (2) includes a placement plate (201) and a fixing plate (202). The fixing plate (202) has a fixing hole (203), and the fixing hole (203) is fixedly connected to the first support hole (4) by a bolt assembly.
10. The integrated container rack with a layer height adjustment mechanism as described in claim 1, characterized in that: The bottom of the partition (2) is provided with an L-shaped connecting plate (204), and the partition mounting assembly (3) is mounted on the L-shaped connecting plate (204).