Ceramic storage device for ceramic production

By combining a motor-driven screw and connecting rod system with helical gears and a bidirectional lead screw design, the ceramic storage device achieves equidistant adjustment and stable positioning, solving the problem of inconvenient operation in existing technologies, improving the stability of the storage device and simplifying the operation process.

CN224477206UActive Publication Date: 2026-07-10JINGDEZHEN YUNJING PORCELAIN CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JINGDEZHEN YUNJING PORCELAIN CO LTD
Filing Date
2025-08-22
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing ceramic storage equipment is inconvenient to operate when adjusting storage space, especially the position adjustment of the partition and support plate is complicated, which affects the stable storage of ceramic vessels.

Method used

The system uses a motor-driven screw to move the first bearing plate and several second bearing plates connected by a connecting rod, achieving equal spacing adjustment. The system also uses a helical gear and a two-way lead screw system to ensure the synchronous lifting and clamping positioning of the bearing plates, simplifying the operation process.

Benefits of technology

It enables equidistant adjustment and stable positioning of ceramic storage devices, simplifies the operation process, improves storage stability, avoids repetitive operations, and protects ceramic ware.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a ceramic storage device for ceramic production, including a box, partitions, a first support plate, and several second support plates. The partitions are vertically arranged inside the box. A motor is installed at the top of the box, and a screw is connected to the output end of the motor. The screw rotates vertically and connects to the box located within the space separated by the partitions. The first support plate is threadedly connected to the screw, and the several second support plates are slidably connected to the screw. In this utility model, the connection of the first, second, and third connecting rods enables the motor to drive the screw to rotate, achieving the lifting effect of the first support plate. At the same time, it enables the synchronous adjustment of the spacing between the several second support plates and between the second support plates adjacent to the first support plate, thereby achieving the effect of equal spacing adjustment of the vertical storage space and achieving the effect of equal spacing storage of ceramics of the same specifications. This solves the problem of inconvenience caused by the need for separate plug-in operations in the prior art.
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Description

Technical Field

[0001] This utility model relates to the field of ceramic storage technology, and in particular to a ceramic storage device for ceramic production. Background Technology

[0002] Utility model CN218641380U discloses a ceramic storage device for ceramic production, including a box body. Multiple partitions are detachably connected inside the box body. A support plate is detachably connected to two adjacent partitions. Slide plates are slidably mounted on both sides of each support plate. A fixing plate is fixed to one end of each slide plate. Two fixing plates are respectively connected to two adjacent partitions. A vertical shaft is rotatably sleeved inside each slide plate. A knob is fixed to the lower end of the vertical shaft. A rotating rod is fixed to the vertical shaft. A third notch is provided on opposite sides of each slide plate, and a slider is slidably mounted within the third notch. The two ends of the rotating rod are rotatably connected to the two sliders respectively. This utility model can well accommodate ceramic vessels of various sizes and is convenient for individual placement, providing good protection and preventing damage to the ceramic vessels.

[0003] After searching, it was found that the existing technology has certain defects. It uses vertically arranged partitions with interchangeable positions and horizontally arranged support plates to adjust the storage space, but the operation is relatively inconvenient. Therefore, there is a need for a ceramic storage device for ceramic production to meet people's needs. Utility Model Content

[0004] The purpose of this invention is to provide a ceramic storage device for ceramic production, so as to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a ceramic storage device for ceramic production, comprising a box, partitions, a first support plate, and several second support plates. The partitions are vertically arranged within the box. A motor is mounted on the top of the box, and a screw is connected to the output end of the motor. The screw is vertically rotatably connected to the box located within the space separated by the partitions. The first support plate is threadedly connected to the screw. Several second support plates are slidably connected to the screw. A first connecting rod is rotatably connected to one side of the first support plate. A second connecting rod is rotatably connected to each second support plate. The middle section of each second connecting rod is rotatably connected to the second support plate. Adjacent second connecting rods are symmetrically rotatably connected to each other. One end of the first connecting rod is symmetrically rotatably connected to the adjacent second connecting rod. A third connecting rod is rotatably connected to the top of the box, and the third connecting rod is symmetrically rotatably connected to the adjacent second connecting rod.

[0006] Preferably, the first bearing plate has a threaded hole, the screw thread is adapted to fit into the threaded hole, and several second bearing plates have through holes, the diameter of the through holes is larger than the outer diameter of the screw, and the screw is arranged in the through holes.

[0007] Preferably, the first support plate and several second support plates are provided with guide blocks on the side near the partition, and guide grooves are provided on the partition. The guide grooves are vertically distributed, and several guide blocks are slidably connected in the guide grooves.

[0008] Preferably, a square shaft is rotatably connected to the outer side of the housing. The square shaft is arranged vertically, and a handwheel is connected to the bottom end of the square shaft. Several first helical gears are slidably connected to the square shaft, and the directions of each first helical gear are the same. A double-acting screw is rotatably connected to both the first and second bearing plates. A first clamping block is threaded to the positive thread section of the double-acting screw, and a second clamping block is threaded to the negative thread section. The first and second clamping blocks are symmetrically slidably connected to each other in the first and second bearing plates, and each has a clamping plate at its top. A second helical gear is connected to one end of each double-acting screw, and each second helical gear meshes with a first helical gear at a corresponding position.

[0009] Preferably, a sliding groove is provided on the side wall of the housing. The sliding groove is arranged vertically, and a number of sliders are slidably connected in the sliding groove. Each slider is L-shaped. One end of the bidirectional lead screw is connected to the second helical gear, and the part of the rod is rotatably connected in the vertical section of the slider. The horizontal section of the slider is arranged above the end face of the first helical gear away from the second helical gear.

[0010] Preferably, the first helical gear has a square hole, the square shaft is arranged in the square hole, and the horizontal section of the slider has a through hole. The diameter of the through hole is the same as the diagonal length of the square shaft, and the square shaft is rotatably connected in the through hole.

[0011] Preferably, a rubber layer is provided on the ends of the two horizontally symmetrical clamps that are close to each other.

[0012] The beneficial effects of this utility model are:

[0013] In this invention, the connection of the first link, the second link, and the third link enables the motor to drive the screw to rotate, thereby achieving the lifting effect of the first bearing plate. At the same time, it enables the synchronous adjustment of the spacing between several second bearing plates and between the second bearing plates adjacent to the first bearing plate, thus achieving the effect of equal spacing adjustment of the vertical storage space and the equal spacing storage effect of ceramics of the same specifications. This solves the problem of inconvenience caused by the need for separate plug-in operation in the prior art.

[0014] This invention utilizes the vertical sliding of several first helical gears on a square shaft, the synchronous relative movement of the first and second clamping blocks driven by a bidirectional lead screw, the connection between the second helical gears and the vertical lead screw, and the meshing effect between the second and first helical gears. This ensures the smooth vertical lifting and lowering of the first and several second bearing plates, while maintaining the axial rotation of the square shaft. This enables the synchronous relative movement between the two clamping plates on the first and several second bearing plates, providing a lateral clamping and positioning effect for ceramics of the same specifications, ensuring the stability of ceramic storage, and is simple to operate, effectively avoiding repetitive operations. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the structure of a ceramic storage device for ceramic production proposed in this utility model;

[0016] Figure 2 This is a side view cross-sectional structural diagram of the screw of a ceramic storage device for ceramic production proposed in this utility model;

[0017] Figure 3 This is a schematic diagram of the first connecting rod, the second connecting rod, and the third connecting structure of a ceramic storage device for ceramic production proposed in this utility model;

[0018] Figure 4 This is a top view cross-sectional structural diagram of the guide block of a ceramic storage device for ceramic production proposed in this utility model;

[0019] Figure 5 This is a front cross-sectional view of a ceramic storage device for ceramic production proposed in this utility model.

[0020] Figure 6 This utility model proposes a ceramic storage device for ceramic production. Figure 5 Enlarged structural diagram at point A in the middle;

[0021] Figure 7 This utility model proposes a ceramic storage device for ceramic production. Figure 5 Enlarged structural diagram at point B.

[0022] In the diagram: 1. Housing; 2. Partition; 3. First bearing plate; 4. Second bearing plate; 5. Motor; 6. Screw; 7. First connecting rod; 8. Second connecting rod; 9. Third connecting rod; 10. Threaded hole; 11. Through hole; 12. Guide block; 13. Guide groove; 14. Square shaft; 15. Handwheel; 16. First helical gear; 17. Double-acting lead screw; 18. First clamping block; 19. Second clamping block; 20. Clamping plate; 21. Second helical gear; 22. Slide groove; 23. Slider; 24. Square hole; 25. Through hole; 26. Rubber layer. Detailed Implementation

[0023] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments.

[0024] Reference Figure 1-7 A ceramic storage device for ceramic production includes a housing 1, partitions 2, a first support plate 3, and several second support plates 4. The partitions 2 are vertically arranged inside the housing 1. A motor 5 is installed at the top of the housing 1, and a screw 6 is connected to the output end of the motor 5. The screw 6 is vertically rotatably connected to the space separated by the partitions 2. The first support plate 3 is threadedly connected to the screw 6. Several second support plates 4 are slidably connected to the screw 6. A first connecting rod 7 is rotatably connected to one side of the first support plate 3. A second connecting rod 8 is rotatably connected to each second support plate 4. The middle section of each second connecting rod 8 is rotatably connected to the second support plate 4. Adjacent second connecting rods 8 are symmetrically rotatably connected to each other. One end of the first connecting rod 7 is symmetrically rotatably connected to the adjacent second connecting rod 8. A third connecting rod 9 is rotatably connected to the top of the housing 1. The third connecting rod 9 is symmetrically rotatably connected to the adjacent second connecting rod 8.

[0025] The connection of the first link 7, the second link 8, and the third link 9 enables the motor 5 to drive the screw 6 to rotate, thereby achieving the lifting effect of the first bearing plate 3. At the same time, it enables the synchronous adjustment of the spacing between several second bearing plates 4 and between the second bearing plates 4 adjacent to the first bearing plate 3, thus achieving the effect of equal spacing adjustment of the vertical storage space and equal spacing storage of ceramics of the same specifications. This solves the problem of inconvenience caused by the need for separate plug-in operation in the prior art.

[0026] Specifically, in this embodiment, the first support plate 3 is provided with a threaded hole 10, and the screw 6 is threadedly fitted into the threaded hole 10. Several second support plates 4 are provided with through holes 11, the diameter of which is larger than the outer diameter of the screw 6. The screw 6 is arranged in the through holes 11. The first support plate 3 achieves a lifting effect under the rotation of the screw 6. Several second support plates 4 do not need to be driven by the screw 6. They can smoothly utilize the connection effect between the first connecting rod 7, the second connecting rod 8 and the third connecting rod 9 to achieve a synchronous lifting effect.

[0027] Specifically, in this embodiment, guide blocks 12 are provided on the side of the first support plate 3 and several second support plates 4 near the partition plate 2. Guide grooves 13 are provided on the partition plate 2. The guide grooves 13 are vertically distributed. Several guide blocks 12 are slidably connected in the guide grooves 13, which improves the stability of the first support plate 3 and several second support plates 4 during the lifting process, as well as the stability during the ceramic bearing process.

[0028] Specifically, in this embodiment, a square shaft 14 is rotatably connected to the outer side of the housing 1. The square shaft 14 is arranged vertically, and a handwheel 15 is connected to the bottom end of the square shaft 14. Several first helical gears 16 are slidably connected to the square shaft 14. The directions of each first helical gear 16 are the same. A bidirectional lead screw 17 is rotatably connected to the first bearing plate 3 and the second bearing plate 4. A first clamping block 18 is threaded to the positive thread section of the bidirectional lead screw 17, and a second clamping block 19 is threaded to the negative thread section. The first clamping block 18 and the second clamping block 19 are symmetrically slidably connected to each other in the first bearing plate 3 and the second bearing plate 4, and a clamping plate 20 is provided at the top of each. A second helical gear 21 is connected to one end of each bidirectional lead screw 17, and each second helical gear 21 meshes with the first helical gear 16 at the corresponding position.

[0029] The handwheel 15 drives the square shaft 14 to rotate axially, which in turn drives the first helical gear 16 to rotate axially. Since each first helical gear 16 has the same direction, combined with the meshing between the first helical gear 16 and the second helical gear 21, the rotation direction of each second helical gear 21 is the same. This makes the rotation direction of each corresponding connecting double-acting screw 17 the same, thereby enabling the first clamping block 18 and the second clamping block 19 on each double-acting screw 17 to perform a synchronous relative clamping effect, clamping and limiting the sides of ceramics of the same specifications, and ensuring stability during storage.

[0030] Specifically, in this embodiment, a sliding groove 22 is provided on the side wall of the housing 1. The sliding groove 22 is arranged vertically, and several sliders 23 are slidably connected in the sliding groove 22. Each slider 23 is L-shaped. One end of the bidirectional lead screw 17 is connected to the second helical gear 21, and the part of the rod is rotatably connected in the vertical section of the slider 23. The horizontal section of the slider 23 is arranged above the end face of the first helical gear 16 away from the second helical gear 21. During the lifting and lowering process, the first bearing plate 3 and several second bearing plates 4 are connected by the sliders 23, which can smoothly drive the second helical gear 21 to perform synchronous lifting and lowering movements. At the same time, the first helical gear 16 is driven to slide vertically on the square shaft 14, ensuring that the first helical gear 16 and the second helical gear 21 are always in a meshing state.

[0031] Specifically, in this embodiment, a square hole 24 is provided on the first helical gear 16, and a square shaft 14 is arranged in the square hole 24. A through hole 25 is provided on the horizontal section of the slider 23. The diameter of the through hole 25 is the same as the diagonal length of the square shaft 14. The square shaft 14 is rotatably connected in the through hole 25, so that the first helical gear 16 can slide axially on the square shaft 14, and the square shaft 14 can smoothly drive the first helical gear 16 to rotate radially. The through hole 25 provides sufficient space for the radial rotation of the square shaft 14.

[0032] Specifically, in this embodiment, a rubber layer 26 is provided on the end of each of the two horizontally symmetrical clamping plates 20 that are close to each other, to provide a cushioning effect and avoid damage to the ceramic during clamping.

[0033] The above are merely preferred embodiments of this utility model, but the scope of protection of this utility model 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 utility model, based on the technical solution and inventive concept of this utility model, should be included within the scope of protection of this utility model.

Claims

1. A ceramic storage device for ceramic production, comprising a housing (1), partitions (2), a first support plate (3), and a plurality of second support plates (4), characterized in that: The partition (2) is vertically arranged inside the box (1). A motor (5) is installed on the top of the box (1). A screw (6) is connected to the output end of the motor (5). The screw (6) is vertically rotatably connected to the space separated by the partition (2) of the box (1). The first bearing plate (3) is threadedly connected to the screw (6). Several second bearing plates (4) are slidably connected to the screw (6). A first connecting rod (7) is rotatably connected to one side of the first bearing plate (3). A second connecting rod (8) is rotatably connected to each second bearing plate (4). The middle section of each second connecting rod (8) is rotatably connected to the second bearing plate (4). Two adjacent second connecting rods (8) are symmetrically rotatably connected to each other. One end of the first connecting rod (7) is symmetrically rotatably connected to the adjacent second connecting rod (8). A third connecting rod (9) is rotatably connected to the top of the box (1). The third connecting rod (9) is symmetrically rotatably connected to the adjacent second connecting rod (8).

2. A ceramic storage device for ceramic production according to claim 1, characterized in that: The first bearing plate (3) has a threaded hole (10) and the screw (6) is threaded into the threaded hole (10). Several second bearing plates (4) have through holes (11) and the diameter of the through hole (11) is larger than the outer diameter of the screw (6). The screw (6) is arranged in the through hole (11).

3. A ceramic storage device for ceramic production according to claim 1, characterized in that: The first bearing plate (3) and several second bearing plates (4) are provided with guide blocks (12) on the side near the partition plate (2). The partition plate (2) is provided with guide grooves (13), which are vertically distributed. Several guide blocks (12) are slidably connected in the guide grooves (13).

4. A ceramic storage device for ceramic production according to claim 1, characterized in that: A square shaft (14) is rotatably connected to the outer side of the housing (1). The square shaft (14) is arranged vertically. A handwheel (15) is connected to the bottom end of the square shaft (14). Several first helical gears (16) are slidably connected to the square shaft (14). Each first helical gear (16) has the same direction. A double-acting screw (17) is rotatably connected to the first bearing plate (3) and the second bearing plate (4). A first clamping block (18) is threaded on the positive thread section of the double-acting screw (17), and a second clamping block (19) is threaded on the negative thread section. The first clamping block (18) and the second clamping block (19) are symmetrically slidably connected to each other in the first bearing plate (3) and the second bearing plate (4), and a clamping plate (20) is provided at the top of each. A second helical gear (21) is connected to one end of each double-acting screw (17). Each second helical gear (21) meshes with the first helical gear (16) at the corresponding position.

5. A ceramic storage device for ceramic production according to claim 1, characterized in that: The side wall of the box (1) is provided with a sliding groove (22), which is arranged vertically. Several sliders (23) are slidably connected in the sliding groove (22). Each slider (23) is L-shaped. One end of the double-acting screw (17) is connected to the second helical gear (21), and the part of the rod is rotatably connected in the vertical section of the slider (23). The horizontal section of the slider (23) is arranged above the end face of the first helical gear (16) away from the second helical gear (21).

6. A ceramic storage device for ceramic production according to claim 4, characterized in that: The first helical gear (16) has a square hole (24) and a square shaft (14) is arranged in the square hole (24). A through hole (25) is provided on the horizontal section of the slider (23). The diameter of the through hole (25) is the same as the diagonal length of the square shaft (14). The square shaft (14) is rotatably connected in the through hole (25).

7. A ceramic storage device for ceramic production according to claim 4, characterized in that: A rubber layer (26) is provided on one end of each of the two horizontally symmetrical clamps (20) that are close to each other.