Magnesite-carbon brick storage rack with size measuring effect
By using limiting components to achieve equidistant distribution and size adjustment of magnesia-carbon brick storage racks, the problem of uneven storage of magnesia-carbon bricks in existing technologies is solved, thereby improving storage efficiency and equipment adaptability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HAIWEI ZHONGXING HIGH-GRADE MAGNESIA BRICK CO LTD
- Filing Date
- 2025-08-28
- Publication Date
- 2026-06-26
AI Technical Summary
Existing magnesia-carbon brick storage racks are difficult to distribute evenly and adjust in size, resulting in wasted storage space and impacting the performance of magnesia-carbon bricks, thus increasing enterprise costs.
A storage rack for magnesia-carbon bricks with dimensional measurement function was designed. It adopts a limiting component including a connecting plate, an L-shaped plate, an inner plate and corner blocks. It achieves equidistant distribution through deflection rods and limiting shafts, and is fixed by bolts and nuts. Anti-slip plates are used to enhance friction and adapt to the placement of magnesia-carbon bricks of different thicknesses.
This technology enables equidistant distribution and size adjustment of magnesia-carbon bricks, improving the utilization rate of storage space, protecting the physical properties of magnesia-carbon bricks, and reducing equipment investment and management difficulty.
Smart Images

Figure CN224410080U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of magnesium-carbon brick storage racks, specifically to a magnesium-carbon brick storage rack with dimensional measurement capabilities. Background Technology
[0002] Magnesia-carbon bricks are made from high-melting-point alkaline oxide magnesium oxide (melting point 2800℃) and high-melting-point carbon materials that are difficult to be wetted by slag, with the addition of various non-oxide additives. Magnesia-carbon bricks are stored in racks, and this storage rack is used for storing magnesia-carbon bricks.
[0003] Most existing storage racks use a fixed layout design, making it difficult for staff to accurately control the spacing between each magnesia-carbon brick when placing them, resulting in uneven distribution of the bricks on the racks. This non-equidistant distribution not only wastes storage space but also affects the physical properties of the magnesia-carbon bricks due to excessively high local stacking density, and may even cause damage to the bricks, increasing enterprise costs.
[0004] Meanwhile, magnesia-carbon bricks of different batches and specifications vary in size, and existing magnesia-carbon brick storage racks generally lack size adjustment functions, making them unable to flexibly adapt to the various shapes and sizes of magnesia-carbon bricks. This results in poor versatility and compatibility of the storage racks, forcing companies to purchase storage racks of multiple specifications when faced with diverse magnesia-carbon brick products, further increasing the investment cost and management difficulty of warehousing equipment;
[0005] Therefore, developing a magnesia-carbon brick storage rack with a defined equidistant distribution function and size adjustment function has become an urgent need to solve the current magnesia-carbon brick storage problem and improve warehouse management efficiency. Utility Model Content
[0006] Technical problems to be solved
[0007] In view of the above-mentioned shortcomings of the existing technology, the present invention provides a magnesium-carbon brick storage rack with size measurement function, which can effectively solve the problems in the existing technology.
[0008] Technical solution
[0009] This utility model provides a magnesium-carbon brick storage rack with dimensional measurement function, including a base frame and a limiting assembly set on the base frame. Two sets of limiting rods are fixed at the top of the base frame. The limiting assembly includes a connecting plate, an L-shaped plate, an inner plate, and corner blocks. The connecting plate is fixedly connected to the base frame through a bottom mounting plate. The L-shaped plate and the inner plate are fixed to the top of the connecting plate, and the L-shaped plate and the inner plate are fixedly connected through a connecting cylinder. A deflection rod and a limiting shaft are fixedly mounted on the outer side of the inner plate. The deflection rod is fixedly sleeved with the corner block. The limiting shaft is set at the top of one side of the corner block. The L-shaped plate has coarse holes and fine holes equidistantly opened in the middle. The deflection rod is inserted into the coarse hole, and the limiting shaft is inserted into the fine hole.
[0010] Furthermore, the erection plate and the connecting plate have straight slots in the middle, and the two are fixedly connected by bolts passing through the straight slots and nuts, and the erection plate is fixedly connected to the base frame.
[0011] Furthermore, each of the corner blocks on both the left and right sides has a through hole on one side, a connecting rod is inserted into the through hole of each corner block, and a nut is fitted on the outside of the connecting rod.
[0012] Furthermore, the limiting rods are located on the left and right sides of the base frame, and one end of the connecting cylinder is fixedly connected to the top frame, and the bottom end of the top frame is fixedly connected to the base frame.
[0013] Furthermore, a groove is provided on one side of the corner block, and an anti-slip sheet is bonded and fixed in the groove, and the top of the corner block has an obtuse angle structure.
[0014] Furthermore, the spacing between the corner pieces in each group is the same.
[0015] Beneficial effects
[0016] This utility model features a limiting component structure. The corner block structure is fixedly connected to the base frame via an L-shaped rod and an inner plate. The corner block is fixedly fitted by a deflection rod within the inner plate. Because of the limiting shaft structure on one side of the corner block, the corner block structure with the limiting shaft can rotate around the deflection rod when it is placed inside the magnesia-carbon brick plate. The plate is then blocked by the limiting shaft, allowing the plate to be placed in the groove. Anti-slip plates enhance friction and aid in connection. The L-shaped plate has coarse and fine holes in the middle, which serve two purposes: first, to fix the deflection rod and limiting shaft; and second, to clamp the inner plate structure inwards. Since each set of corner blocks is equidistantly distributed, the user can adjust the spacing to specify the required interval, facilitating the placement of magnesia-carbon bricks of different thicknesses. The bottom of the connecting plate connects to the mounting plate via a straight groove, allowing for adjustment of the lateral spacing during fixing. Therefore, combined with this spacing adjustment function, this device is more suitable for on-site storage processes. Attached Figure Description
[0017] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0018] Figure 1 This is a schematic diagram of the structure of this utility model;
[0019] Figure 2 This is a front view of the structure of this utility model;
[0020] Figure 3 This is an exploded view of the structure of this utility model;
[0021] Figure 4 This is a structural exploded view of the L-shaped plate and inner plate in this utility model.
[0022] The labels in the diagram represent: 1. Base frame; 11. Limiting rod; 12. Top frame; 2. Limiting component; 21. Erection board; 22. Connecting plate; 23. L-shaped plate; 231. Coarse hole; 232. Fine hole; 233. Connecting cylinder; 24. Corner block; 241. Deflection rod; 242. Limiting shaft; 243. Groove; 244. Anti-slip plate; 25. Connecting rod; 26. Inner plate. Detailed Implementation
[0023] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some, not all, of the embodiments of this utility model. All other embodiments obtained by those skilled in the art based on the embodiments of this utility model without creative effort are within the scope of protection of this utility model.
[0024] The present invention will be further described below with reference to the embodiments.
[0025] Example: A magnesium-carbon brick storage rack with dimensional measurement function, see attached figure. Figure 1 -Appendix Figure 4 The system includes a base frame 1 and a limiting assembly 2 mounted on the base frame 1. Two sets of limiting rods 11 are fixed to the top of the base frame 1. The limiting assembly 2 includes a connecting plate 22, an L-shaped plate 23, an inner plate 26, and a corner block 24. The connecting plate 22 is fixedly connected to the base frame 1 through a bottom mounting plate 21. The L-shaped plate 23 and the inner plate 26 are fixed to the top of the connecting plate 22 and are fixedly connected to each other through a connecting cylinder 233. A deflection rod 241 and a limiting shaft 242 are fixed to the outside of the inner plate 26. The deflection rod 241 is fixedly sleeved with the corner block 24. The limiting shaft 242 is located at the top of one side of the corner block 24. The L-shaped plate 23 has coarse holes 231 and fine holes 232 equidistantly opened in the middle. The deflection rod 241 is inserted into the coarse hole 231, and the limiting shaft 242 is inserted into the fine hole 232.
[0026] The erection plate 21 and the connecting plate 22 have straight slots in the middle, and the two are fixedly connected by bolts passing through the straight slots and nuts. The erection plate 21 is also fixedly connected to the base frame 1.
[0027] Each of the corner blocks 24 on both the left and right sides has a through hole on one side, and a connecting rod 25 is inserted into the through hole of each corner block 24 on both sides, and a nut is fitted on the outside of the connecting rod 25; the limiting rod 11 is set on the left and right sides of the base frame 1, and one end of the connecting cylinder 233 is fixedly connected to the top frame 12, and the bottom end of the top frame 12 is fixedly connected to the base frame 1; a groove 243 is opened on one side of each corner block 24, and an anti-slip piece 244 is glued and fixed in the groove 243, and the top of each corner block 24 has an obtuse angle structure; the spacing between each group of corner blocks 24 is the same.
[0028] Through the set limiting component 2 structure, the corner block 24 structure can be fixedly connected to the base frame 1 via the L-shaped rod and the inner plate 26. The corner block 24 is fixedly sleeved by the deflection rod 241 in the inner plate 26. Due to the limiting shaft 242 structure set on one side of the corner block 24, the corner block 24 structure with the limiting shaft 242 can rotate around the deflection rod 241 when it is placed inside the corner block 24 with the magnesium carbon brick plate. It is blocked by the limiting shaft 242. The plate can be placed in the groove 243 and the friction is enhanced by the anti-slip plate 244 to assist. The L-shaped plate 23 has a coarse hole 231 and a fine hole 232 in the middle. These holes serve two purposes: first, they can be used to fix the deflection rod 241 and the limiting shaft 242; second, they can be used to clamp the inner plate 26. Since each set of corner blocks 24 is equidistantly distributed, the user can adjust the distribution spacing of the corner blocks 24 according to the required spacing, which is convenient for placing magnesia-carbon bricks of different thicknesses. The bottom of the connecting plate 22 is connected to the erecting plate 21 through a straight groove. Therefore, the lateral spacing can be adjusted as needed during fixing. With the aforementioned spacing adjustment function, this device is more suitable for on-site storage processes.
[0029] The above embodiments are only used to illustrate the technical solutions of this utility model, and are not intended to limit it. Although this utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions will not cause the essence of the corresponding technical solutions to deviate from the protection scope of the technical solutions of the embodiments of this utility model.
Claims
1. A magnesium-carbon brick storage rack with dimensional measurement function, characterized in that, The system includes a base frame (1) and a limiting assembly (2) mounted on the base frame (1). Two sets of limiting rods (11) are fixed to the top of the base frame (1). The limiting assembly (2) includes a connecting plate (22), an L-shaped plate (23), an inner plate (26), and corner blocks (24). The connecting plate (22) is fixedly connected to the base frame (1) through a bottom mounting plate (21). The L-shaped plate (23) and the inner plate (26) are fixed to the top of the connecting plate (22), and the L-shaped plate (23) and the inner plate (26) are positioned close to each other. The inner plate (26) is fixedly connected by a connecting tube (233). A deflection rod (241) and a limiting shaft (242) are fixed on the outer side of the inner plate (26). The deflection rod (241) is fixedly sleeved with the corner block (24). The limiting shaft (242) is set at the top of one side of the corner block (24). The middle part of the L-shaped plate (23) is provided with coarse holes (231) and fine holes (232) at equal intervals. The deflection rod (241) is inserted into the coarse hole (231), and the limiting shaft (242) is inserted into the fine hole (232).
2. A magnesium-carbon brick storage rack with dimensional measurement function according to claim 1, characterized in that, The erection plate (21) and the connecting plate (22) have straight slots in the middle, and the two are fixedly connected by bolts through the straight slots and nuts. The erection plate (21) is fixedly connected to the base frame (1).
3. A magnesium-carbon brick storage rack with dimensional measurement function according to claim 1, characterized in that, Each of the corner blocks (24) on the left and right sides has a through hole on one side, and a connecting rod (25) is inserted into the through hole of the corner blocks (24) on both sides, and a nut is fitted on the outside of the connecting rod (25).
4. A magnesium-carbon brick storage rack with dimensional measurement function according to claim 1, characterized in that, The limiting rod (11) is set on the left and right sides of the base frame (1), and one end of the connecting tube (233) is fixedly connected to the top frame (12), and the bottom end of the top frame (12) is fixedly connected to the base frame (1).
5. A magnesium-carbon brick storage rack with dimensional measurement function according to claim 4, characterized in that, A groove (243) is provided on one side of the corner block (24), and an anti-slip sheet (244) is glued and fixed in the groove (243). The top of the corner block (24) is an obtuse angle structure.
6. A magnesium-carbon brick storage rack with dimensional measurement function according to claim 1, characterized in that, The spacing between the corner blocks (24) in each group is the same.