A wood fiber cellulose sponge processing mold and a wood fiber cellulose sponge thereof

By designing an automated wood pulp cellulose sponge processing mold, the problem of adapting the equipment to diverse product specifications was solved, achieving efficient and precise sponge cutting and stable product quality.

CN224407715UActive Publication Date: 2026-06-26JIANGSU HENGFU NEW MATERIALS TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGSU HENGFU NEW MATERIALS TECH CO LTD
Filing Date
2025-06-11
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing processing equipment cannot flexibly adapt to the diverse specifications of wood pulp cellulose sponge products, resulting in high production costs and unstable product quality.

Method used

A wood pulp cellulose sponge processing mold was designed, which includes components such as a sponge conveying platform, support columns, a sponge bearing platform, a limiting U-shaped groove, a sliding bracket, and an electric push rod, to achieve automated cutting and positioning and adapt to the processing of sponges of different sizes and shapes.

Benefits of technology

It improves the versatility and production efficiency of the equipment, ensures the precision and consistency of cutting, reduces the difficulty of operation, and extends the service life of the sponge.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

A kind of wood fiber cellulose sponge processing mould, the inside of sponge bearing table is equipped with wood fiber cellulose sponge, the size of sponge bearing table is adapted according to the size of wood fiber cellulose sponge, there is interval between sponge conveying platform and sponge bearing table, the lower end of sponge conveying platform is equipped with fixed block and limiting U-shaped groove fixed by welding, a pair of fixed blocks are arranged in total in the lower end of sponge conveying platform, two limiting U-shaped grooves are arranged in total in the lower end of sponge conveying platform, and fixed block is located in the two limiting U-shaped grooves.This utility model can realize the positioning of wood fiber cellulose sponge with different sizes and shapes by setting limiting U-shaped groove below sponge conveying platform and using sliding bracket for sliding adjustment.Meanwhile, the position of sliding bracket is further fixed by first butterfly bolt on fixed block, ensuring the stability during conveying, adapting to the processing needs of wood fiber cellulose sponge with various specifications, improving equipment versatility;Reducing manual intervention, reducing operation difficulty and improving production efficiency.
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Description

Technical Field

[0001] This utility model belongs to the field of wood pulp cellulose sponge processing technology, specifically a wood pulp cellulose sponge processing mold and its wood pulp cellulose sponge. Background Technology

[0002] Wood pulp cellulose sponge is a porous material with excellent water absorption, making it suitable for cleaning items. It offers several advantages: good elasticity, quickly returning to its original shape; wear resistance, maintaining good performance over extended periods; lightweight, facilitating handling and installation; waterproof and moisture-proof, resisting mold and mildew; maintains softness even at low temperatures; and is resistant to various chemicals.

[0003] In existing technologies, current processing equipment can often only handle wood pulp cellulose sponges of fixed sizes and shapes, failing to flexibly adapt to diverse product specifications. Whenever a new product needs to be produced, molds must be redesigned or replaced, increasing production and management costs. Traditional cutting processes are typically manual or semi-automatic, making it difficult to guarantee consistency and accuracy in each cut, resulting in inconsistent product quality.

[0004] To address this issue, a wood pulp cellulose sponge processing mold and the wood pulp cellulose sponge thereof are provided, thus resolving the aforementioned problems. Utility Model Content

[0005] In view of the above situation and to overcome the defects of the prior art, this utility model provides a wood pulp cellulose sponge processing mold and the wood pulp cellulose sponge thereof, so as to at least partially solve the above technical problems.

[0006] The technical solution adopted by this utility model is as follows:

[0007] This utility model proposes a wood pulp cellulose sponge processing mold, comprising:

[0008] A processing base is provided, on which a sponge transport platform, a support column, and a sponge support platform are connected and fixed by welding. The sponge support platform contains wood pulp cellulose sponge, and its dimensions are adapted to the dimensions of the wood pulp cellulose sponge. There is a gap between the sponge transport platform and the sponge support platform. The lower end of the sponge transport platform is provided with a fixing block and a limiting U-shaped groove, both fixed by welding. There is a pair of fixing blocks and two limiting U-shaped grooves at the lower end of the sponge transport platform. The fixing block is located between the two limiting U-shaped grooves, and the limiting U-shaped grooves slide upwards. The system is equipped with a sliding bracket, and the fixing block is provided with a first wing bolt to fix the sliding bracket. The upper end of the sliding bracket is rotatably provided with a first pulley. The middle of the sponge conveying platform is provided with a second pulley to support the glue scraper. A third pulley support column is also connected to one side of the sponge conveying platform and fixed by a threaded connection. A third pulley bracket is slidably provided on the third pulley support column. The third pulley bracket is also provided with a second wing bolt for fixing. A third pulley is also provided on the third pulley bracket. The lower end of the support column is connected with a storage battery.

[0009] As a further embodiment of this utility model: the support column is provided with a temperature sensor, a signal sensor and a lighting lamp in sequence on the battery; a first electric push rod is connected between the sponge transport platform and the sponge support platform on the support column; the first electric push rod is provided with a cutting blade; the cutting blade is located above the wood pulp cellulose sponge; and a rectangular through hole is provided on the sponge support platform.

[0010] As a further embodiment of this utility model: a material feeding bracket is provided on one side of the sponge support platform, a second electric push rod is connected to the material feeding bracket, a material feeding push plate is connected to the second electric push rod, and the material feeding push plate passes through a rectangular through hole when moving up and down.

[0011] As a further improvement of this utility model: the feeding bracket is provided with a screw, a pressure sensor is rotatably mounted on the screw, a support plate is connected to the pressure sensor on the side away from the screw, a groove is provided on one side of the sponge support platform, a scale is provided on the other side, and a control panel and a fan for cooling are also provided on the support column.

[0012] As a further improvement of this utility model, the lower end of the processing base is provided with a threaded hole for easy fixing.

[0013] As a further improvement of this utility model: two sliding brackets are provided, and the sliding brackets are symmetrical.

[0014] As a further improvement of this invention, the fan is located on the upper side of the control panel.

[0015] As a further embodiment of this utility model: a wood pulp cellulose sponge processed by a wood pulp cellulose sponge processing mold, wherein the wood pulp cellulose sponge is disposed inside a sponge support platform, and the processed wood pulp cellulose sponge retains a protective film around its perimeter. The shape of the wood pulp cellulose sponge includes, but is not limited to, rectangular, cylindrical, and elongated shapes.

[0016] Implementing the embodiments of this utility model will have the following beneficial effects:

[0017] This embodiment achieves positioning of wood pulp cellulose sponges of different sizes and shapes by setting a limiting U-shaped groove under the sponge conveying platform and using a sliding bracket for sliding adjustment. Simultaneously, the position of the sliding bracket is further fixed by the first wing bolt on the fixing block, ensuring stability during transportation. This allows the system to adapt to the processing needs of various specifications of wood pulp cellulose sponges, improving equipment versatility; reducing manual intervention, lowering operational difficulty, and increasing production efficiency.

[0018] In this embodiment, the second pulley is used to support the scraper. The adjustable pulley group, consisting of the third pulley support column, the third pulley bracket, and the third pulley, can adjust the pulley position according to actual needs to meet specific process requirements and adapt to complex and changing working environments. It also facilitates maintenance and replacement of parts, extending service life.

[0019] In this embodiment, the first electric push rod drives the cutting blade to move along a predetermined trajectory, thereby completing the precise cutting of the wood pulp cellulose sponge. Compared with traditional manual or semi-automatic cutting methods, this method has a high degree of automation, ensuring consistency and accuracy in each cut and significantly improving product quality.

[0020] This embodiment allows for various geometric shapes of wood pulp cellulose sponges, such as rectangular, cylindrical, and strip shapes, to meet the needs of different industries for different types of wood pulp cellulose sponges. A protective film is retained around the perimeter of the wood pulp cellulose sponge, effectively protecting the product from external contamination, especially during transportation or storage. Furthermore, it helps maintain the product's original appearance and performance characteristics, extending its service life.

[0021] The above overview is for illustrative purposes only and is not intended to be limiting in any way. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features of the present invention will become readily apparent from the accompanying drawings and the following detailed description. Attached Figure Description

[0022] To more clearly illustrate the technical solutions in the embodiments of this application 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 application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0023] Figure 1 This is the first isometric schematic diagram of the wood pulp cellulose sponge processing mold of this utility model.

[0024] Figure 2 This is a second isometric schematic diagram of the wood pulp cellulose sponge processing mold of this utility model.

[0025] Figure 3 This is a front view of the wood pulp cellulose sponge processing mold of this utility model.

[0026] Figure 4 yes Figure 1 Schematic diagram at point M.

[0027] Figure 5 This is a schematic diagram of the structure of the wood pulp cellulose sponge of this utility model.

[0028] As shown in the figure: 1. Processing base; 2. Sponge conveying platform; 3. Support column; 4. Sponge bearing platform; 5. Fixing block; 6. Limiting U-shaped groove; 7. Sliding bracket; 8. First wing bolt; 9. First pulley; 10. Second pulley; 11. Third pulley support column; 12. Third pulley bracket; 13. Second wing bolt; 14. Third pulley; 15. Battery; 16. Temperature sensor; 17. Signal sensor; 18. Lighting lamp; 19. First electric push rod; 20. Cutting blade; 21. Unloading bracket; 22. Second electric push rod; 23. Unloading push plate; 24. Screw; 25. Pressure sensor; 26. Support plate; 27. Groove; 28. Scale; 29. ​​Control panel; 30. Fan; 31. Threaded hole; 32. Wood pulp cellulose sponge; 33. Protective film.

[0029] The accompanying drawings are provided to further understand the present invention and form part of the specification. They are used together with the embodiments of the present invention to explain the present invention and do not constitute a limitation thereof. Detailed Implementation

[0030] In the following description, only certain exemplary embodiments are briefly described. As those skilled in the art will recognize, the described embodiments can be modified in various ways without departing from the spirit or scope of this invention. Therefore, the drawings and description are considered exemplary in nature and not restrictive.

[0031] It is important to note that the terms "first," "second," etc., are used only to distinguish between descriptive and positional descriptions, and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Therefore, features specified with "first," etc., may explicitly or implicitly include one or more of that feature; similarly, when the quantity of certain features is not limited by words such as "two" or "three," it should be noted that such features also explicitly or implicitly include one or more features.

[0032] In the embodiments of this utility model, unless otherwise explicitly specified and limited, terms such as "installation," "connection," and "fixation" should be interpreted broadly; for example, they can refer to a fixed connection, a detachable connection, or an integral molding; they can refer to a mechanical connection, a direct connection, a welding connection, or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the accompanying drawings and specific circumstances.

[0033] In the description of the embodiments of this utility model, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on the embodiments of this utility model.

[0034] like Figures 1 to 5As shown, a wood pulp cellulose sponge processing mold includes: a processing base 1, on which a sponge conveying platform 2, a support column 3, and a sponge support platform 4 are connected and fixed by welding. The sponge support platform 4 contains wood pulp cellulose sponge 32, and its dimensions are adapted to the dimensions of the wood pulp cellulose sponge 32. There is a gap between the sponge conveying platform 2 and the sponge support platform 4. The lower end of the sponge conveying platform 2 is provided with a fixing block 5 and a limiting U-shaped groove 6 fixed by welding. A pair of fixing blocks 5 are provided at the lower end of the sponge conveying platform 2, and two limiting U-shaped grooves 6 are provided at the lower end of the sponge conveying platform 2. The fixing block 5 is located between the two limiting U-shaped grooves 6. A sliding bracket 7 is slidably mounted on the U-shaped groove 6. A first wing bolt 8, which serves to fix the sliding bracket 7, is mounted on the fixing block 5. A first pulley 9 is rotatably mounted on the upper end of the sliding bracket 7. A second pulley 10, which serves to support the glue scraper, is mounted in the middle of the sponge conveying platform 2. A third pulley support column 11, which is fixed by a threaded connection, is also connected to one side of the sponge conveying platform 2. A third pulley bracket 12 is slidably mounted on the third pulley support column 11. The third pulley bracket 12 can slide on the third pulley support column 11. A second wing bolt 13, which serves to fix the third pulley bracket 12, is also mounted on the third pulley bracket 12. A third pulley 14 is also mounted on the third pulley bracket 12. A storage battery 15 is connected to the lower end of the support column 3.

[0035] In the specific application of this utility model embodiment, the sponge support platform 4 is adapted to the size of the wood pulp cellulose sponge 32 to ensure that the sponge can be placed stably during processing, avoiding movement or deformation. A certain gap exists between the sponge transport platform 2 and the sponge support platform 4, providing necessary space for sponge transport and allowing the wood pulp cellulose sponge to be easily moved from the transport platform to the support platform for subsequent processing. The sliding bracket 7 slides on the limiting U-shaped groove 6. Through the fixing action of the first butterfly bolt 8, the position of the sliding bracket can be adjusted, thereby controlling the height and position of the first pulley 9. This allows the pulley to be flexibly adjusted according to processing requirements, ensuring the stability of the wood pulp cellulose sponge during transport.

[0036] The second pulley 10 is located in the middle of the sponge conveying platform 2, serving to support the glue scraper. During processing, the glue scraper moves smoothly via the second pulley, evenly smoothing the wood pulp cellulose sponge. The third pulley support 11 is fixed to one side of the sponge conveying platform 2 via a threaded connection. The third pulley bracket 12 slides on the third pulley support and is fixed by the second wing bolt 13, allowing the position of the third pulley 14 to be flexibly adjusted according to processing requirements, ensuring precise positioning and smooth movement of the wood pulp cellulose sponge during processing.

[0037] Battery 15 is connected to the lower end of support column 3. The selection of battery ensures the continuity and stability of the processing process and avoids processing interruption due to insufficient power. Processing base 1, sponge conveying platform 2, and support column 3 ensure the overall stability and durability of the mold, enabling the mold to withstand greater loads and impacts during processing, ensuring processing quality and safety.

[0038] Place the wood pulp cellulose sponge 32 on the sponge support platform 4, ensuring it is stable and does not move. Adjust the position of the sliding bracket 7 and fix it with the first butterfly bolt 8 so that the first pulley 9 maintains proper contact with the wood pulp cellulose sponge. Transport the wood pulp cellulose sponge from the sponge support platform 4 to the processing area.

[0039] During processing, the second pulley 10 supports the scraper to move smoothly and evenly flatten the wood pulp cellulose sponge. The position of the third pulley 14 is flexibly adjusted according to processing requirements to ensure precise positioning and smooth movement of the wood pulp cellulose sponge.

[0040] In one possible implementation, the support column 3 is sequentially equipped with a temperature sensor 16, a signal sensor 17, and a lighting lamp 18 on the battery 15. A first electric push rod 19 is connected on the support column 3 between the sponge conveying platform 2 and the sponge support platform 4. The first electric push rod 19 is equipped with a cutting blade 20, which is located above the wood pulp cellulose sponge 32. The sponge support platform 4 is equipped with a rectangular through hole. A feeding bracket 21 is provided on one side of the sponge support platform 4. A second electric push rod 22 is connected to the feeding bracket 21. A feeding push plate 23 is connected to the second electric push rod 22. The feeding push plate 23 passes through the rectangular through hole when moving up and down.

[0041] In the specific application of this utility model embodiment, the temperature sensor 16 monitors the temperature inside the mold or the surrounding environment in real time to ensure that the temperature is kept within a suitable range during processing, avoiding the impact of excessively high or low temperatures on processing quality. The signal sensor 17 is used to detect the working status of the mold or the position of the wood pulp cellulose sponge, providing accurate signal input to the control system and ensuring the precision of the processing. The first electric push rod 19 is set on the support column 3, and its telescopic movement drives the cutting blade 20 to move up and down. When the wood pulp cellulose sponge is transported to the designated position, the first electric push rod is activated, and the cutting blade descends rapidly to cut the sponge.

[0042] The material and shape of the cutting disc 20 are determined according to the material and cutting requirements of the wood pulp cellulose sponge to ensure a smooth and precise cutting process. The sponge support platform 4 is provided with a rectangular through hole to provide a falling channel for the cut sponge fragments, avoiding the accumulation of fragments during the cutting process and ensuring the continuity of the processing.

[0043] The feeding bracket 21 is connected to one side of the sponge support platform 4, providing stable support for the second electric push rod 22. The telescopic movement of the second electric push rod 22 drives the feeding push plate 23 to move up and down. After cutting is completed, the second electric push rod is activated, and the feeding push plate rises rapidly, pushing the cut sponge fragments out of the rectangular through hole, thus completing the feeding process. The shape and size of the feeding push plate 23 match the rectangular through hole to ensure a smooth and precise feeding process. At the same time, its material selection also considers wear resistance to extend its service life.

[0044] The wood pulp cellulose sponge is transported to the sponge support platform 4 and fixed in position. Temperature sensor 16 monitors the temperature inside or around the mold in real time, signal sensor 17 detects the position and status of the sponge, and lighting 18 provides sufficient light so that the operator can clearly observe the processing.

[0045] When the sponge is positioned at the cutting point, the first electric push rod 19 is activated, causing the cutting blade 20 to descend rapidly and precisely cut the sponge. After cutting, the cutting blade 20 rises back to its initial position, and at the same time, the second electric push rod 22 is activated, causing the feeding push plate 23 to rise and push the cut sponge fragments out of the rectangular through hole.

[0046] In one possible implementation, the feeding bracket 21 is provided with a screw 24, and a pressure sensor 25 is rotatably mounted on the screw 24. A support plate 26 is connected to the pressure sensor 25 on the side away from the screw 24. A groove 27 is provided on one side of the sponge support platform 4, and a scale 28 is provided on the other side. The support column 3 is also provided with a control panel 29 and a fan 30 for cooling. The lower end of the processing base 1 is provided with a threaded hole 31 for easy fixing. There are two sliding brackets 7, which are symmetrical. The fan 30 is located above the control panel 29.

[0047] In the specific application of this utility model embodiment, the sponge support platform 4 stably supports the wood pulp cellulose sponge, ensuring its stability during processing. A groove 27 on one side facilitates the positioning and fixing of the sponge, while a scale 28 on the other side provides precise dimensional references, allowing operators to accurately control the cutting or processing dimensions of the sponge. The feeding bracket 21 is connected to the pressure sensor 25 via a screw 24, forming a stable feeding mechanism. After the wood pulp cellulose sponge is processed, the screw 24 adjusts the height of the feeding bracket by rotation, while the pressure sensor 25 monitors pressure changes in real time during the feeding process, ensuring smooth and safe feeding.

[0048] The support plate 26 is connected to the pressure sensor 25, providing support and buffering to further enhance the stability of the feeding process. The pressure sensor 25 monitors pressure changes in real time during feeding and transmits the signal to the control panel 29. Through the control panel 29, the operator can view the pressure sensor readings in real time to ensure the smoothness and safety of the feeding process. Simultaneously, the control panel can automatically adjust the screw rotation speed or the height of the feeding bracket based on the feedback from the pressure sensor to achieve precise pressure control.

[0049] Fan 30 is positioned above control panel 29 to provide cooling. During processing, friction and cutting operations generate heat, causing the mold temperature to rise. Fan 30 effectively lowers the mold temperature by blowing cool air, preventing overheating from affecting processing quality or damaging mold components. Control panel 29 can also control the fan speed of 30, intelligently adjusting it based on the actual mold temperature. When the mold temperature rises, the control panel automatically increases the fan speed to accelerate heat dissipation; when the mold temperature drops to a suitable range, the control panel reduces the fan speed to save energy.

[0050] The lower end of the machining base 1 is provided with threaded holes 31 for easy fixing, allowing the mold to be firmly installed on the machining equipment and ensuring the stability and safety of the mold during the machining process. Two sliding supports 7 are provided, symmetrically distributed, to provide stable support and a sliding track for the mold. During machining, the sliding supports 7 ensure smooth movement and precise positioning of the mold, improving machining accuracy and efficiency.

[0051] The operator places the wood pulp cellulose sponge on the sponge support platform 4 and adjusts it to the appropriate size according to the scale 28. The processing program of the mold is started through the control panel 29, and the screw 24 starts to rotate to adjust the height of the feeding bracket 21. At the same time, the pressure sensor 25 monitors the pressure changes in real time during the feeding process. When the sponge is processed to the specified depth, the control panel 29 automatically stops the rotation of the screw according to the feedback of the pressure sensor and starts the fan 30 for cooling.

[0052] After processing, the operator controls the movement of the sliding bracket 7 via the control panel 29 to move the mold to the unloading position. At this time, the screw 24 continues to rotate to adjust the height of the unloading bracket 21, smoothly pushing out the processed wood pulp cellulose sponge.

[0053] In one possible implementation, the wood pulp cellulose sponge 32 is processed by a wood pulp cellulose sponge processing mold and is disposed inside the sponge support platform 4. The processed wood pulp cellulose sponge 32 has a protective film 33 around its perimeter. The shape of the wood pulp cellulose sponge 32 includes, but is not limited to, rectangular, cylindrical and elongated shapes.

[0054] In a specific application of this utility model embodiment, the wood pulp cellulose sponge 32 is placed inside the sponge support platform 4. The support platform is equipped with a precise positioning device to ensure the stability of the sponge during processing. The support platform also has a clamping device or an adsorption device inside to further fix the sponge and prevent displacement during processing. During the cutting process, the shape and speed of the cutting tool can be adjusted according to the shape and thickness of the wood pulp cellulose sponge to ensure the flatness and precision of the cut surface.

[0055] During processing, a protective film 33 is applied around the wood pulp cellulose sponge 32. The protective film 33 is applied to the sponge surface by spraying, pasting or other means. The protective film 33 protects the sponge from damage during processing, prevents debris from splashing during cutting, and keeps the processing environment clean. After processing, the protective film is left around the sponge to provide additional protection.

[0056] The shape of the wood pulp cellulose sponge 32 is not limited to rectangular, cylindrical, and strip shapes. It can also be customized according to actual needs. By changing different shaped cutting tools or adjusting processing parameters, different shapes of wood pulp cellulose sponge can be easily processed.

[0057] In practical use, in Example 1, the wood pulp cellulose sponge is placed on the sponge transport platform. The sponge is transported smoothly on the platform by a combination of sliding brackets and pulleys. The sliding bracket is fixed to the limiting U-shaped groove by the first wing bolt and its position can be adjusted as needed to accommodate sponges of different sizes.

[0058] During transportation, the second pulley supports the scraper and prevents the sponge from deforming or being damaged.

[0059] Specifically, the wood pulp cellulose sponge is transported to the sponge support platform, the size of which is adapted to the size of the sponge to ensure the stability of the sponge during the cutting process. Temperature sensors and signal sensors installed on the support columns monitor the ambient temperature and processing status in real time, providing accurate feedback information to the control panel.

[0060] Specifically, once the sponge is positioned, the first electric push rod is activated, moving the cutting blade downwards to precisely cut the wood pulp cellulose sponge. The shape and size of the cutting blade can be changed according to actual needs to adapt to the processing requirements of different shapes of wood pulp cellulose sponges. During the cutting process, the heat generated by the cutting blade is effectively controlled by the cooling effect of a fan, preventing excessive temperature from affecting the quality of the sponge.

[0061] Specifically, after cutting, the second electric push rod is activated, pushing the feeding plate downwards and ejecting the cut wood pulp cellulose sponge through the rectangular through-hole of the sponge support platform. The screw and pressure sensor on the feeding bracket work together to monitor pressure changes in real time during the feeding process, ensuring a smooth and safe process.

[0062] Specifically, the threaded holes at the bottom of the processing base facilitate fixing the entire mold on the workbench, improving the stability of the processing. The processed wood pulp cellulose sponge retains a protective film around its perimeter, protecting the sponge surface from scratches or contamination.

[0063] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0064] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

[0065] The present invention and its embodiments have been described above. This description is not restrictive, and the accompanying drawings are only one embodiment of the present invention; the actual structure is not limited thereto. In conclusion, if those skilled in the art are inspired by this description and design similar structures and embodiments without departing from the inventive spirit of the present invention, such designs should fall within the protection scope of the present invention.

Claims

1. A wood fiber cellulose sponge processing mold characterized by, include: A processing base (1) is connected to a sponge transport platform (2), a support column (3), and a sponge support platform (4) that are fixed by welding. The sponge support platform (4) contains a wood pulp cellulose sponge (32). The size of the sponge support platform (4) is adapted to the size of the wood pulp cellulose sponge (32). There is a gap between the sponge transport platform (2) and the sponge support platform (4). The lower end of the sponge transport platform (2) is provided with a fixing block (5) and a limiting U-shaped groove (6) that are fixed by welding. There is a pair of fixing blocks (5) at the lower end of the sponge transport platform (2). There are two limiting U-shaped grooves (6) at the lower end of the sponge transport platform (2). The fixing block (5) is located between the two limiting U-shaped grooves (6). The limiting U-shaped groove (6) is slidably provided with The sliding bracket (7) is provided with a first butterfly bolt (8) on the fixed block (5) to fix the sliding bracket (7). The upper end of the sliding bracket (7) is provided with a first pulley (9). The middle of the sponge conveying platform (2) is provided with a second pulley (10) to support the glue scraper. The side of the sponge conveying platform (2) is also connected with a third pulley support column (11) fixed by a threaded connection. The third pulley support column (11) is slidably provided with a third pulley bracket (12). The third pulley bracket (12) can slide on the third pulley support column (11). The third pulley bracket (12) is also provided with a second butterfly bolt (13) to fix it. The third pulley bracket (12) is also provided with a third pulley (14). The lower end of the support column (3) is connected with a storage battery (15).

2. The wood fiber cellulose sponge processing mold according to claim 1, characterized by, The support column (3) is provided with a temperature sensor (16), a signal sensor (17) and a lighting lamp (18) in sequence on the battery (15). A first electric push rod (19) is connected between the sponge transport platform (2) and the sponge support platform (4) on the support column (3). A cutting blade (20) is provided on the first electric push rod (19). The cutting blade (20) is located above the wood pulp cellulose sponge (32). A rectangular through hole is provided on the sponge support platform (4).

3. The wood fiber cellulose sponge processing mold according to claim 1, wherein, The sponge support platform (4) is provided with a feeding bracket (21) on one side. A second electric push rod (22) is connected to the feeding bracket (21). A feeding push plate (23) is connected to the second electric push rod (22). The feeding push plate (23) passes through a rectangular through hole when moving up and down.

4. The wood fiber cellulose sponge processing mold according to claim 3, characterized by, The feeding bracket (21) is provided with a screw (24), and a pressure sensor (25) is rotatably provided on the screw (24). The pressure sensor (25) is connected to a support plate (26) on the side away from the screw (24). The sponge support platform (4) is provided with a groove (27) on one side and a scale (28) on the other side. The support column (3) is also provided with a control panel (29) and a fan (30) for cooling.

5. The wood pulp cellulose sponge processing mold according to claim 1, characterized in that, The processing base (1) has a threaded hole (31) at its lower end for easy fixing.

6. The wood pulp cellulose sponge processing mold according to claim 1, characterized in that, There are two sliding brackets (7), and the sliding brackets (7) are symmetrical.

7. The wood pulp cellulose sponge processing mold according to claim 4, characterized in that, The fan (30) is located on the upper side of the control panel (29).

8. A wood pulp cellulose sponge processed using a wood pulp cellulose sponge processing mold according to any one of claims 1-7, characterized in that, The wood pulp cellulose sponge (32) is located inside the sponge support platform (4). The processed wood pulp cellulose sponge (32) has a protective film (33) around its perimeter. The shape of the wood pulp cellulose sponge (32) includes, but is not limited to, rectangular, cylindrical and elongated shapes.