Moisture absorbing mechanism for ceramic production
By setting moisture absorption holes of different diameters and flow regulation components on the outer wall of the moisture absorption cylinder, the problem of the moisture absorption mechanism being unable to absorb water vapor evenly is solved, achieving efficient water vapor absorption and humidity control, and improving the quality and efficiency of ceramic production.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FOSHAN ZHANDA INTELLIGENT TECH CO LTD
- Filing Date
- 2025-08-01
- Publication Date
- 2026-07-07
AI Technical Summary
Existing moisture-absorbing mechanisms cannot absorb moisture evenly, especially for moisture clumps with large diameters at the bottom, resulting in poor moisture absorption and low efficiency.
Design a moisture absorption mechanism with several moisture absorption holes of different diameters on the outer wall of the moisture absorption cylinder to form a moisture absorption zone, and equipped with a flow adjustment component. The moisture absorption efficiency is adjusted by adjusting the contact area between the upper and lower spaces. The diameter of the moisture absorption holes increases sequentially, and the holes are arranged in a staggered "品" shape.
The moisture absorption mechanism achieves uniform absorption of water vapor at different heights, improving moisture absorption efficiency and space utilization, ensuring the uniformity of humidity in the ceramic production workshop, and increasing the pass rate of ceramic blanks.
Smart Images

Figure CN224464934U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of moisture absorption technology, and in particular to a moisture absorption mechanism for ceramic production. Background Technology
[0002] Ceramic production workshops have extremely strict requirements for humidity control. During the ceramic production process, the ceramic blanks need to be kept at a suitable level of dryness. If the humidity in the workshop is too high, the blanks cannot be dried effectively, resulting in excessive moisture content. This can easily lead to cracking and deformation during subsequent firing, seriously affecting product quality. Moreover, a high-humidity environment will prolong the production cycle, reduce production efficiency, and increase energy consumption. Therefore, in order to ensure efficient ceramic production and product quality, ceramic production workshops urgently need to be equipped with reliable moisture-absorbing devices to accurately control workshop humidity and ensure the smooth operation of the production process.
[0003] Existing moisture-absorbing mechanisms have uniformly sized suction holes, resulting in similar suction power from top to bottom. They are effective at absorbing small-diameter water vapor from the top, but less effective at absorbing large-diameter water vapor from the bottom. They cannot absorb water vapor evenly from top to bottom, leading to poor moisture absorption and low efficiency. Utility Model Content
[0004] In view of the shortcomings of the existing technology, the purpose of this utility model is to provide a moisture absorption mechanism for ceramic production, which can solve the problems of the moisture absorption mechanism being unable to absorb water vapor evenly from top to bottom, resulting in poor moisture absorption effect and low efficiency.
[0005] The objective of this utility model is achieved through the following technical solution:
[0006] A moisture-absorbing mechanism for ceramic production includes a moisture-absorbing cylinder, which is a hollow cylindrical structure. The outer wall of the moisture-absorbing cylinder has several first moisture-absorbing holes, several second moisture-absorbing holes, and several third moisture-absorbing holes, which together form a moisture-absorbing zone. The first, second, and third moisture-absorbing holes are arranged in multiple rows and evenly distributed on the moisture-absorbing cylinder. The second moisture-absorbing holes are located above the third moisture-absorbing holes, and the first moisture-absorbing holes are located above the second moisture-absorbing holes. The diameters of the first, second, and third moisture-absorbing holes increase sequentially. The moisture-absorbing zone is located in the middle of the moisture-absorbing cylinder and surrounds the cylinder horizontally. A flow rate regulating component is provided on the moisture-absorbing cylinder, located above the moisture-absorbing zone. The flow rate regulating component divides the interior of the moisture-absorbing cylinder into an upper space and a lower space, and is used to adjust the horizontal contact area between the upper space and the lower space.
[0007] Preferably, the flow regulating component includes a space regulating plate disposed inside the moisture-absorbing cylinder. The space regulating plate has a placement groove, and a rotating rod is horizontally disposed on the placement groove. A fastener is fixedly disposed on the space regulating plate. The rotating rod is disposed between the space regulating plate and the fastener and is in contact with both of them. Both ends of the rotating rod are rotatably connected to the moisture-absorbing cylinder, and one end extends to the outside of the moisture-absorbing cylinder. A paddle is fixedly sleeved on one end of the rotating rod, and the paddle is disposed on the outside of the moisture-absorbing cylinder.
[0008] Preferably, an adjusting seat is fixedly provided on the outer wall of the moisture-absorbing cylinder, an adjusting plate is fixedly provided on the adjusting seat, the adjusting plate is sleeved on the rotating rod and the two are rotatably connected, a plurality of adjusting holes are provided on the adjusting plate, an insertion hole is provided at the end of the lever away from the rotating rod, and an insertion rod is provided outside the moisture-absorbing cylinder, the insertion rod is inserted into the adjusting hole and the insertion hole.
[0009] Preferably, the adjusting plate has a fan-shaped plate structure, and a plurality of the adjusting holes are evenly distributed at the arc-shaped end of the adjusting plate.
[0010] Preferably, a cap is fixedly provided at the end of the insertion rod away from the moisture-absorbing cylinder.
[0011] Preferably, the placement groove has an arc-shaped structure, the curvature of which matches the rotating rod, and the contact surface between the fastener and the rotating rod is also an arc-shaped structure that matches the rotating rod.
[0012] Preferably, the space adjustment plate is a circular plate structure, and its diameter matches the inner diameter of the moisture absorption cylinder.
[0013] Preferably, the first moisture-absorbing holes in each row, the second moisture-absorbing holes in each row, and the third moisture-absorbing holes in each row are arranged alternately with the moisture-absorbing holes in the next row.
[0014] Preferably, the first moisture-absorbing hole, the second moisture-absorbing hole, and the third moisture-absorbing hole are all circular hole structures.
[0015] Preferably, the top and bottom of the moisture-absorbing cylinder are respectively fixedly fitted with connecting plates, and a plurality of tenon and mortise parts are evenly fixedly arranged on the connecting plates, the tenon and mortise parts being used to fix the connecting flange.
[0016] The beneficial effects of this utility model are:
[0017] The moisture-absorbing mechanism for ceramic production of this utility model has several first moisture-absorbing holes, several second moisture-absorbing holes, and several third moisture-absorbing holes on the outer wall of the moisture-absorbing cylinder, which together form a moisture-absorbing zone. The second moisture-absorbing holes are located above the third moisture-absorbing holes, and the first moisture-absorbing holes are located above the second moisture-absorbing holes. The diameter of the first, second, and third moisture-absorbing holes increases sequentially. The moisture-absorbing cylinder is equipped with a flow regulating component, which is located above the moisture-absorbing zone. This allows the moisture-absorbing mechanism for ceramic production to uniformly absorb water vapor from different height levels. The space utilization rate of the moisture-absorbing zone is high, and the moisture absorption effect is significant. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0019] Figure 2 for Figure 1 A magnified view of a portion of region A;
[0020] Figure 3 This is a cross-sectional view of the present invention;
[0021] Figure 4 This is a schematic diagram of the flow regulation component in this utility model;
[0022] Figure 5 This is a schematic diagram of the structure of the placement groove in this utility model;
[0023] Figure 6 This is a diagram showing the positional relationship between the connecting plate and the tenon joint in this utility model.
[0024] In the diagram: 10, moisture-absorbing cylinder; 20, first moisture-absorbing hole; 30, second moisture-absorbing hole; 40, third moisture-absorbing hole; 50, moisture-absorbing zone; 60, flow rate adjustment assembly; 61, space adjustment plate; 62, placement slot; 63, rotating rod; 64, fastener; 65, lever; 70, upper space; 80, lower space; 90, adjustment seat; 100, adjustment plate; 110, adjustment hole; 120, insertion hole; 130, insertion rod; 140, insertion cap; 150, connecting plate; 160, tenon and mortise joint. Detailed Implementation
[0025] To make the technical problems solved, the technical solutions and the beneficial effects of the utility model clearer, the utility model will be further described below in conjunction with the accompanying drawings and embodiments.
[0026] The embodiments provided by this utility model are as follows: Figures 1-6As shown, a moisture-absorbing mechanism for ceramic production includes a moisture-absorbing cylinder 10, which is a hollow cylindrical structure. The outer wall of the moisture-absorbing cylinder 10 has several first moisture-absorbing holes 20, several second moisture-absorbing holes 30, and several third moisture-absorbing holes 40, which together form a moisture-absorbing zone 50. The first moisture-absorbing holes 20, several second moisture-absorbing holes 30, and several third moisture-absorbing holes 40 are arranged in multiple rows and evenly distributed on the moisture-absorbing cylinder 10. The second moisture-absorbing holes 30 are located above the third moisture-absorbing holes 40, and the first moisture-absorbing holes 20 are located above the second moisture-absorbing holes 40. Above the moisture absorption hole 30, the diameters of the first moisture absorption hole 20, the second moisture absorption hole 30, and the third moisture absorption hole 40 increase sequentially. The moisture absorption zone 50 is located in the middle of the moisture absorption cylinder 10 and surrounds the moisture absorption cylinder 10 in the horizontal direction. A flow regulating component 60 is provided on the moisture absorption cylinder 10. The flow regulating component 60 is located above the moisture absorption zone 50. The flow regulating component 60 divides the interior of the moisture absorption cylinder 10 into an upper space 70 and a lower space 80. The flow regulating component 60 is used to adjust the horizontal contact area between the upper space 70 and the lower space 80.
[0027] In use, the staff places the moisture absorption mechanism in the ceramic production workshop and connects the dehumidification fan to the top of the moisture absorption cylinder 10. The dehumidification fan is then turned on, and the dehumidification fan drives the air in the moisture absorption cylinder 10 to flow towards the dehumidification fan. Under the action of air pressure, the water vapor in the production workshop passes through the moisture absorption holes and enters the moisture absorption cylinder 10, eventually flowing towards the dehumidification fan. Due to the influence of gravity, the water vapor in the ceramic production workshop is distributed with a gradually increasing size from top to bottom. Water vapor of different sizes enters the moisture absorption cylinder 10 through the first moisture absorption hole 20, the second moisture absorption hole 30, and the third moisture absorption hole 40, respectively, resulting in high moisture absorption efficiency. In addition, the staff can adjust the horizontal contact area of the upper space 70 and the lower space 80 by adjusting the flow rate adjustment component 60, thereby adjusting the water vapor absorption efficiency.
[0028] The pore diameter of the moisture absorption holes in this solution can be adjusted according to the actual conditions of the ceramic production workshop. Preferably, the pore diameter of the first moisture absorption hole 20 is 12mm, the pore diameter of the second moisture absorption hole 30 is 15mm, and the pore diameter of the third moisture absorption hole 40 is 20mm.
[0029] The moisture-absorbing cylinder 10 in this solution is made by rolling stainless steel sheet metal parts. A sheet of material for the moisture-absorbing cylinder 10 is cut out from the wide edge of the stainless steel sheet metal raw material to avoid wasting materials.
[0030] Preferably, the flow regulating assembly 60 includes a space regulating plate 61, which is disposed inside the moisture absorption cylinder 10. A placement groove 62 is provided on the space regulating plate 61, and a rotating rod 63 is horizontally disposed on the placement groove 62. A fastener 64 is fixedly disposed on the space regulating plate 61. The rotating rod 63 is disposed between the space regulating plate 61 and the fastener 64 and is in contact with both of them. Both ends of the rotating rod 63 are rotatably connected to the moisture absorption cylinder 10, and one end extends to the outside of the moisture absorption cylinder 10. A paddle 65 is fixedly sleeved on one end of the rotating rod 63, and the paddle 65 is disposed on the outside of the moisture absorption cylinder 10.
[0031] Preferably, an adjustment seat 90 is fixedly installed on the outer wall of the moisture absorption cylinder 10, and an adjustment plate 100 is fixedly installed on the adjustment seat 90. The adjustment plate 100 is sleeved on the rotating rod 63, and the two are rotatably connected. The adjustment plate 100 has several adjustment holes 110. The end of the lever 65 away from the rotating rod 63 has an insertion hole 120. An insertion rod 130 is installed outside the moisture absorption cylinder 10. The insertion rod 130 is inserted into the adjustment holes 110 and the insertion hole 120. The operator controls the fixed position of the lever 65 through the insertion rod 130, thereby realizing stable control of the opening and closing angle of the space adjustment plate 61.
[0032] Preferably, the adjusting plate 100 has a fan-shaped plate structure, and a number of adjusting holes 110 are evenly distributed on the arc-shaped end of the adjusting plate 100. This arrangement makes the opening and closing angles of the space adjusting plate 61 corresponding to different adjusting holes 110 more uniform and the moisture absorption effect more stable.
[0033] Preferably, a cap 140 is fixedly provided at the end of the insertion rod 130 away from the moisture absorption cylinder 10. The cap 140 makes it easier for staff to pick up and insert the insertion rod 130, making the operation more labor-saving.
[0034] Preferably, the placement groove 62 has an arc-shaped structure, the curvature of which matches the rotating rod 63. The contact surface between the fastener 64 and the rotating rod 63 is also an arc-shaped structure that matches the rotating rod 63. This arrangement makes the placement groove 62, the rotating rod 63 and the fastener 64 fit more tightly, and prevents the rotating rod 63 from shaking without affecting its rotation, thereby improving the stability of the flow regulating component 60.
[0035] Preferably, the space adjustment plate 61 is a circular plate structure with a diameter that matches the inner diameter of the moisture absorption cylinder 10, so that the space adjustment plate 61 can adjust the moisture absorption effect to the maximum extent and provide a good user experience.
[0036] Preferably, the first moisture absorption holes 20, the second moisture absorption holes 30, and the third moisture absorption holes 40 in each row are staggered with the moisture absorption holes in the next row. This staggered arrangement makes the moisture absorption holes arranged in a "pin" shape. Compared with the traditional "grid" arrangement, after the moisture absorption cylinder 10 is curled into a cylindrical structure, the positions of the moisture absorption holes in all parts of the space are more reasonable, and the moisture absorption effect can be more fully exerted. At the same time, the "pin"-shaped arrangement of the moisture absorption holes makes the stress on each part of the sheet metal material of the moisture absorption cylinder 10 uniform after punching, ensuring the overall hardness. In addition, the "pin"-shaped arrangement makes the overall moisture absorption mechanism more beautiful.
[0037] Preferably, the first moisture absorption hole 20, the second moisture absorption hole 30, and the third moisture absorption hole 40 are all circular hole structures. Circular moisture absorption holes are easier to absorb water vapor in the air, and the design is more reasonable.
[0038] Preferably, connecting plates 150 are fixedly sleeved on the top and bottom of the moisture absorption cylinder 10 respectively. A number of tenon and mortise parts 160 are uniformly and fixedly arranged on the connecting plates 150. The setting of the tenon and mortise parts 160 facilitates the subsequent quick positioning of the ground fixing flange and the top connecting flange with the moisture absorption cylinder 10 respectively, which is beneficial to the overall welding reinforcement of the moisture absorption mechanism, saves production time, and ensures the production quality of the moisture absorption mechanism. In this preferred solution, the number of tenon and mortise parts 160 on the connecting plate 150 is 3. The width of the bottom tenon and mortise part 160 is 15.96 mm, and the height is 3 mm. The width of the top tenon and mortise part 160 is 21.95 mm, and the height is 3 mm.
[0039] The working principle in this embodiment is more specifically as follows:
[0040] The staff places the moisture absorption mechanism in the ceramic production workshop and quickly positions it through the tenon and mortise parts 160. A moisture exhaust fan is connected to the top of the moisture absorption cylinder 10, and the moisture exhaust fan is started. The moisture exhaust fan drives the air in the moisture absorption cylinder 10 to flow towards the moisture exhaust fan. Under the action of air pressure, the water vapor in the production workshop passes through the moisture absorption holes and enters the moisture absorption cylinder 10, and finally flows towards the moisture exhaust fan. Since the water vapor in the ceramic production workshop is affected by gravity, the size of the water vapor gradually increases from top to bottom. Water vapor of different sizes enters the moisture absorption cylinder 10 through the first moisture absorption holes 20, the second moisture absorption holes 30, and the third moisture absorption holes 40 respectively, and the moisture absorption efficiency is high. In addition, the staff can manually rotate the dial 65. The dial 65 drives the rotating rod 63 to rotate, and then drives the space adjustment plate 61 to rotate, realizing the adjustment of the opening and closing angle of the space adjustment plate 61. When the space adjustment plate 61 rotates to the appropriate position, the staff inserts the insertion rod 130 into the adjustment hole 110 and the insertion hole 120 to complete the fixation of the dial 65. By adjusting the contact area in the horizontal direction between the upper space 70 and the lower space 80 in the above way, the moisture absorption efficiency can be adjusted.
[0041] In the ceramic production workshop, the humidity varies in different areas. The moisture absorption mechanism equipped with the flow regulation component 60 can be installed in various positions in the workshop. By manually adjusting the opening and closing degree of the space adjustment plate 61 of the moisture absorption mechanism in different positions, the humidity uniformity of the entire production workshop can be controlled, the moisture absorption effect is good, and the overall qualification rate of ceramic blanks is effectively improved.
[0042] The moisture-absorbing mechanism for ceramic production of this utility model has several first moisture-absorbing holes 20, several second moisture-absorbing holes 30, and several third moisture-absorbing holes 40 on the outer wall of the moisture-absorbing cylinder 10, which together form a moisture-absorbing zone 50. The second moisture-absorbing holes 30 are located above the third moisture-absorbing holes 40, and the first moisture-absorbing holes 20 are located above the second moisture-absorbing holes 30. The diameter of the first moisture-absorbing holes 20, the second moisture-absorbing holes 30, and the third moisture-absorbing holes 40 increases sequentially. The moisture-absorbing cylinder 10 is equipped with a flow rate regulating component 60, which is located above the moisture-absorbing zone 50. This allows the moisture-absorbing mechanism for ceramic production to uniformly absorb water vapor from different height levels. The space utilization rate of the moisture-absorbing zone 50 is high, and the moisture absorption effect is significant.
[0043] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the present utility model shall fall within the protection scope of the present utility model.
Claims
1. A moisture-absorbing mechanism for ceramic production, comprising a moisture-absorbing cylinder (10), characterized in that: The moisture-absorbing cylinder (10) is a hollow cylindrical structure. Several first moisture-absorbing holes (20), several second moisture-absorbing holes (30), and several third moisture-absorbing holes (40) are provided on the outer wall of the moisture-absorbing cylinder (10), and these three together form a moisture-absorbing area (50). The first moisture-absorbing holes (20), the second moisture-absorbing holes (30), and the third moisture-absorbing holes (40) are arranged in multiple rows and evenly distributed on the moisture-absorbing cylinder (10). The second moisture-absorbing holes (30) are located above the third moisture-absorbing holes (40), and the first moisture-absorbing holes (20) are located above the second moisture-absorbing holes (30). The aperture sizes of the second moisture-absorbing hole (30) and the third moisture-absorbing hole (40) increase sequentially. The moisture-absorbing area (50) is located in the middle of the moisture-absorbing cylinder (10) and surrounds the moisture-absorbing cylinder (10) in the horizontal direction. A flow regulating component (60) is provided on the moisture-absorbing cylinder (10). The flow regulating component (60) is located above the moisture-absorbing area (50). The flow regulating component (60) divides the interior of the moisture-absorbing cylinder (10) into an upper space (70) and a lower space (80). The flow regulating component (60) is used to adjust the horizontal contact area between the upper space (70) and the lower space (80).
2. The moisture-absorbing mechanism for ceramic production according to claim 1, characterized in that: The flow regulating component (60) includes a space regulating plate (61), which is disposed inside the moisture-absorbing cylinder (10). A placement groove (62) is provided on the space regulating plate (61), and a rotating rod (63) is horizontally disposed on the placement groove (62). A fastener (64) is fixedly disposed on the space regulating plate (61). The rotating rod (63) is disposed between the space regulating plate (61) and the fastener (64) and is in contact with both of them. Both ends of the rotating rod (63) are rotatably connected to the moisture-absorbing cylinder (10), and one end extends to the outside of the moisture-absorbing cylinder (10). A paddle (65) is fixedly sleeved on one end of the rotating rod (63), and the paddle (65) is disposed outside the moisture-absorbing cylinder (10).
3. The moisture-absorbing mechanism for ceramic production according to claim 2, characterized in that: An adjusting seat (90) is fixedly installed on the outer wall of the moisture-absorbing cylinder (10). An adjusting plate (100) is fixedly installed on the adjusting seat (90). The adjusting plate (100) is sleeved on the rotating rod (63) and the two are rotatably connected. Several adjusting holes (110) are opened on the adjusting plate (100). An insertion hole (120) is opened at the end of the lever (65) away from the rotating rod (63). An insertion rod (130) is provided outside the moisture-absorbing cylinder (10). The insertion rod (130) is inserted into the adjusting hole (110) and the insertion hole (120).
4. The moisture-absorbing mechanism for ceramic production according to claim 3, characterized in that: The adjusting plate (100) has a fan-shaped plate structure, and a plurality of adjusting holes (110) are evenly distributed at the arc-shaped end of the adjusting plate (100).
5. The moisture-absorbing mechanism for ceramic production according to claim 3, characterized in that: A cap (140) is fixedly provided at the end of the insertion rod (130) away from the moisture-absorbing cylinder (10).
6. The moisture-absorbing mechanism for ceramic production according to claim 2, characterized in that: The placement groove (62) has an arc-shaped structure, and its curvature matches that of the rotating rod (63). The contact surface between the fastener (64) and the rotating rod (63) is also an arc-shaped structure that matches that of the rotating rod (63).
7. The moisture-absorbing mechanism for ceramic production according to claim 2, characterized in that: The space adjustment plate (61) is a circular plate structure, and its diameter matches the inner diameter of the moisture-absorbing cylinder (10).
8. The moisture-absorbing mechanism for ceramic production according to claim 1, characterized in that: The first moisture-absorbing hole (20) in each row, the second moisture-absorbing hole (30) in each row, and the third moisture-absorbing hole (40) in each row are arranged alternately with the moisture-absorbing holes in the next row.
9. A moisture-absorbing mechanism for ceramic production according to claim 1, characterized in that: The first moisture-absorbing hole (20), the second moisture-absorbing hole (30) and the third moisture-absorbing hole (40) are all circular hole structures.
10. A moisture-absorbing mechanism for ceramic production according to claim 1, characterized in that: The top and bottom of the moisture-absorbing cylinder (10) are respectively fixedly fitted with connecting plates (150), and a number of tenon and mortise parts (160) are evenly fixed on the connecting plates (150). The tenon and mortise parts (160) are used to fix the connecting flange.