A smart filter press device and process suitable for silicone

The design of the intelligent filter press device enables automatic separation and cleaning of the filter cloth and filter plate, solving the problem of filter cloth clogging and improving the efficiency and effect of organosilicon filtration.

CN118045405BActive Publication Date: 2026-06-23TONGXIANG RONGLI CHEM

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
TONGXIANG RONGLI CHEM
Filing Date
2024-01-31
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

In existing filter press devices, the filter cloth surface is easily clogged and difficult to clean when filtering organosilicon, which affects the filtration effect.

Method used

An intelligent filter press device was designed, including a cleaning mechanism, a driving mechanism, a switching mechanism, and a separation mechanism. It can automatically separate the filter cloth from the filter plate after the filter press is completed, clean the filter residue using a cleaning rod and a scraper, and further clean the residue on the surface of the filter cloth using a toggle rod and a brush.

Benefits of technology

This achieves effective separation of the filter cloth and filter plate, ensuring that the filter residue on the surface of the filter cloth can be thoroughly cleaned, avoiding clogging, and improving filtration efficiency and effectiveness.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a kind of intelligent filter-pressing devices and processes suitable for organic silicon of filter-pressing device technical field, including support seat, the front and rear ends of the support seat are all fixedly connected with main beam, and the side away from support seat between two main beams is fixedly connected with thrust plate;After the end of filter-pressing, external controller will control drive block to open filter plate one by one, filter cake falls off, during the movement of filter plate, filter cloth will be separated from filter plate under the action of separation plate, which is conducive to the separation of filter cloth and filter plate, the filter residue attached to the surface of filter cloth can be separated from filter plate, which is convenient for subsequent cleaning, to avoid filter cloth and filter plate sticking together during cleaning, filter residue will be closely attached to the surface of filter cloth and filter plate during filter-pressing, which makes it difficult to clean;Subsequently, the filter residue on the surface of filter cloth will be scraped off by scraping block, which is conducive to cleaning the filter residue remaining on the surface of filter cloth after one filter-pressing, to avoid the influence of residual filter residue on the filtering effect of filter cloth.
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Description

Technical Field

[0001] This invention relates to the field of filter press technology, specifically to an intelligent filter press device and process suitable for organosilicon. Background Technology

[0002] Organosilicon, or organosilicon compounds, refers to compounds containing Si-C bonds, with at least one organic group directly bonded to a silicon atom. Conventionally, compounds whose organic groups are bonded to silicon atoms through oxygen, sulfur, nitrogen, etc., are also considered organosilicon compounds. Among them, polysiloxanes, composed of silicon-oxygen bonds as their backbone, are the most numerous, most extensively studied, and most widely used type of organosilicon compound, accounting for over 90% of total usage.

[0003] In existing technologies, when using a filter press to filter organosilicon, the operation is usually continuous. During continuous operation, the filter cake usually falls off under its own gravity. During the squeezing process, solid residues often remain on the surface of the filter cloth, clogging the filter cloth and affecting the subsequent filtration effect. Furthermore, the filter cloth sticks to the surface of the filter plate during the squeezing process, making it even more difficult to clean the filter cloth. Summary of the Invention

[0004] The purpose of this invention is to provide an intelligent filter press device and process that enables the filter cloth to be separated from the filter plate and then cleaned, so as to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, the present invention provides the following technical solution: an intelligent filter press device suitable for organosilicon, comprising a support base, with main beams fixedly connected to both ends of the support base, a thrust plate fixedly connected between the two main beams on the side away from the support base, a connection port being provided in the middle of the thrust plate, a hydraulic cylinder fixedly connected to the surface of the support base on the side away from the thrust plate, a pressing plate fixedly connected to the hydraulic cylinder through the rear end of the support base, the pressing plate sliding between the two main beams, multiple filter plates slidably connected between the two main beams, each of the multiple filter plates having a communication port in the middle, through holes being provided at the four corners of the filter plate surface, and recesses being provided in the middle portions of both sides of the filter plate. The filter plate has a recessed position that communicates with a through hole. Filter cloth is provided on both sides of the filter plate corresponding to the recessed positions. A driving block is slidably connected to the surface of the main beam. The driving block is controlled by an external driver. A cleaning mechanism is provided at the upper end of the filter plate. The cleaning mechanism can clean the residual filter residue on the surface of the filter cloth. A driving mechanism is provided above the thrust plate. The driving mechanism can drive the cleaning mechanism to move up and down for cleaning. A switching mechanism is provided on one side of the driving mechanism. The switching mechanism can switch to moving upward after the cleaning mechanism finishes cleaning the filter cloth downwards. A separation mechanism is provided on the surface of the filter plate. The separation mechanism can separate the filter cloth from the filter plate before the cleaning mechanism cleans.

[0006] As a further embodiment of the present invention, the cleaning mechanism includes two fixing blocks, which are respectively fixedly connected to the front and rear sides of the upper end of the filter plate. Both sides of the two fixing blocks are slidably connected to racks, and the bottom of the two racks on the same side are jointly fixedly connected to a cleaning rod. Multiple scraping blocks are elastically slidably connected to the surface of the cleaning rod near the filter plate.

[0007] As a further embodiment of the present invention, the driving mechanism includes multiple support plates, which are fixedly connected to the upper end of the fixed block. The support plates are respectively located on both sides of the rack. A rotating rod is rotatably connected between the support plates on both sides of the rack. The rotating rod passes through the support plates. A first gear is fixedly connected to the surface of the rotating rod at the middle position of the two support plates. The first gear meshes with the rack. A second gear is fixedly connected to the surface of the rotating rod near the main beam. The upper end of the support base and the front and rear sides of the upper end of the pressure plate are both fixedly connected to a driving rail. The second gear is located inside the driving rail. Partial driving teeth are fixedly connected to the bottom of the driving rail near the pressure plate and the upper part near the support base. The driving teeth can act on the second gear.

[0008] As a further embodiment of the present invention, the switching mechanism includes two switching plates, which are respectively fixedly connected to the front and rear sides of the upper end of the support base and the upper end of the pressing plate. A switching groove is formed on the surface of the switching plate, and the middle position of the switching groove is an inclined groove. The rotating rod is located in the switching groove, and the support plate is formed with a through groove corresponding to the position of the rotating rod.

[0009] As a further embodiment of the present invention, the separation mechanism includes an installation rod, which is fixedly connected to the upper end of the filter cloth. The side of the installation rod near the filter plate is inclined, and an arc-shaped groove is formed on the surface of the side of the installation rod near the filter plate. The filter plate has an installation groove corresponding to the position of the installation rod, and the bottom part of the installation groove is inclined. The installation rod is located in the installation groove. A separation plate is slidably connected between the corresponding racks on the front and rear sides. The part of the separation plate corresponding to the position of the installation groove extends downward. The bottom of the separation plate is inclined, and a separation groove is formed on the surface of the separation plate. The separation groove penetrates the separation plate, and the bottom of the separation groove is arc-shaped. A push plate is elastically connected to the upper end of the separation plate. The push plate extends into the separation groove. An arc-shaped locking plate is hinged to the bottom of the push plate. The locking plate can engage with the groove. The side of the push plate away from the separation groove slides between the corresponding racks on the front and rear sides. A pressure rod is elastically slidably connected to the middle position between the corresponding racks on the front and rear sides through a gas spring. The pressure rod can act on the push plate.

[0010] As a further embodiment of the present invention, an arc-shaped groove is formed on the surface of the cleaning rod near the filter cloth. A rotating shaft is rotatably connected inside the groove, and the rotating shaft passes through the cleaning rod. Multiple soft actuating rods are fixedly connected to the surface of the cleaning rod inside the groove. A rotating column is rotatably connected to the upper end of the rack surface. Multiple fixing plates are fixedly connected to the surface of the fixing block. A tensioning column is elastically rotatably connected to the surface of the fixing plate via a gas spring. A transmission belt is connected to the rotating rod surface, the tensioning column surface, the rotating column surface, and the rotating shaft surface.

[0011] As a further embodiment of the present invention, a brush is fixedly connected to the surface of the cleaning rod;

[0012] A smart pressure filtration process suitable for organosilicon, the specific steps of which are as follows:

[0013] Step 1: Before pressing and filtering the organosilicon, the filter press device needs to be started first. The hydraulic cylinder will press multiple filter plates together.

[0014] Step 2: Then, introduce the silicone to be filtered into the filter plate through the connection port. The silicone will gradually fill the depressions between the filter plates.

[0015] Step 3: Then, gas is introduced into it through the through hole, and the moisture in the organosilicon will flow out;

[0016] Step 4: After the filter press is completed, when the filter plate is opened, the cleaning mechanism will clean the surface of the filter cloth under the action of the drive mechanism;

[0017] Step 5: During the cleaning process, the separation mechanism will separate the filter cloth from the filter plate, making it easier to clean the filter residue;

[0018] Step Six: Switching the mechanism will then restore the cleaning mechanism to its original position.

[0019] Compared with the prior art, the beneficial effects of the present invention are:

[0020] 1. After the filter press is completed, the external controller controls the drive block to open the filter plates one by one, and the filter cake falls off. During the movement of the filter plates, the filter cloth will detach from the filter plates under the action of the separation plate, which is conducive to the separation of the filter cloth from the filter plates. The filter residue attached to the surface of the filter cloth can be separated from the filter plates, which is convenient for subsequent cleaning. This avoids the filter cloth sticking to the filter plates during cleaning, as the filter residue will stick tightly to the surface of the filter cloth and the filter plates during the filter press, making it difficult to clean. Subsequently, the scraping block will scrape off the filter residue on the surface of the filter cloth, which is conducive to cleaning the filter residue remaining on the surface of the filter cloth after one filter press, and avoids the residual filter residue affecting the filtration effect of the filter cloth, resulting in a decrease in subsequent filtration efficiency.

[0021] 2. During the cleaning process of the filter cloth, the actuating rod on the rotating shaft surface taps the filter cloth surface, which helps to clean the smaller filter residues attached to the filter cloth surface, ensuring the filtration effect of the filter cloth. This avoids the situation where the scraper removes larger filter residues from the filter cloth surface, leaving smaller filter residues that cannot be cleaned, thus affecting the filtration effect of the filter cloth and reducing the filtration efficiency.

[0022] 3. In the process of cleaning the filter cloth, the cleaning brush can remove the filter residue adhering to the surface of the filter cloth, ensuring the cleaning effect of the filter cloth and improving the filtration efficiency. Attached Figure Description

[0023] Figure 1 This is a process flow diagram of the present invention;

[0024] Figure 2 This is a schematic diagram of the overall structure of the present invention;

[0025] Figure 3 This is a schematic diagram of the overall structure of the present invention with the filter plate concealed.

[0026] Figure 4 This is a schematic diagram of the filter plate structure in this invention;

[0027] Figure 5 for Figure 4 Schematic diagram of the structure at point A in the middle;

[0028] Figure 6 for Figure 4 Schematic diagram of the structure at point B;

[0029] Figure 7 This is a schematic diagram of the structure after the filter plate and filter cloth explode apart in this invention;

[0030] Figure 8 This is a schematic diagram of the cleaning mechanism on one side of the fixed block in this invention;

[0031] Figure 9 for Figure 8 Schematic diagram of the structure at point C;

[0032] Figure 10 This is a schematic diagram showing the drive rail, switching plate, and the connection relationship between the first gear, the second gear, and the rotating rod in this invention.

[0033] Figure 11 for Figure 10 Schematic diagram of the structure at point D;

[0034] Figure 12 This is a schematic diagram of the structure of the filter plate after it has been cut open in this invention;

[0035] Figure 13 for Figure 12 Schematic diagram of the structure at point E in the middle;

[0036] Figure 14 This is a schematic diagram showing the connection relationship between the separation plate, the push plate, the cleaning rod, and the rack in this invention;

[0037] Figure 15 for Figure 14 Schematic diagram of the structure at point F.

[0038] The attached diagram lists the components represented by each number as follows:

[0039] Support base 1, main beam 2, thrust plate 3, connection port 4, hydraulic cylinder 5, clamping plate 6, filter plate 7, connecting port 8, through hole 9, filter cloth 10, drive block 11, fixing block 12, rack 13, cleaning rod 14, scraping block 15, support plate 16, rotating rod 17, first gear 18, second gear 19, drive rail 20, drive gear 21, switching plate 22, switching groove 23, through groove 24, mounting rod 25, slot 26, mounting groove 27, separation plate 28, separation groove 29, push plate 30, snap-fit ​​plate 31, pressure rod 32, groove 33, rotating shaft 34, actuating rod 35, rotating column 36, fixing plate 37, tensioning column 38, transmission belt 39, brush 40. Detailed Implementation

[0040] Please see Figures 1-15 This invention provides a technical solution: an intelligent filter press device suitable for organosilicon, comprising a support base 1, with main beams 2 fixedly connected to both ends of the support base 1, a thrust plate 3 fixedly connected between the two main beams 2 on the side away from the support base 1, a connection port 4 in the middle of the thrust plate 3, a hydraulic cylinder 5 fixedly connected to the surface of the support base 1 on the side away from the thrust plate 3, a pressing plate 6 fixedly connected to the rear end of the hydraulic cylinder 5, the pressing plate 6 sliding between the two main beams 2, multiple filter plates 7 slidably connected between the two main beams 2, each of the multiple filter plates 7 having a connecting port 8 in the middle, through holes 9 at the four corners of the surface of each filter plate 7, and recesses in the middle of both sides of each filter plate 7. The filter plate 7 has a recessed position that is connected to the through hole 9. Filter cloth 10 is provided on both sides of the filter plate 7 at the corresponding recessed positions. A drive block 11 is slidably connected to the surface of the main beam 2. The drive block 11 is controlled by an external driver. A cleaning mechanism is provided at the upper end of the filter plate 7. The cleaning mechanism can clean the residual filter residue on the surface of the filter cloth 10. A drive mechanism is provided above the thrust plate 3. The drive mechanism can drive the cleaning mechanism to move up and down for cleaning. A switching mechanism is provided on one side of the drive mechanism. The switching mechanism can switch to moving upward after the cleaning mechanism has finished cleaning the filter cloth 10 downward. A separation mechanism is provided on the surface of the filter plate 7. The separation mechanism can separate the filter cloth 10 from the filter plate 7 before the cleaning mechanism cleans.

[0041] The cleaning mechanism includes two fixed blocks 12, which are fixedly connected to the front and rear sides of the upper end of the filter plate 7 respectively. Both sides of the two fixed blocks 12 are slidably connected to racks 13. The bottom of the two racks 13 on the same side is fixedly connected to a cleaning rod 14. Multiple scraping blocks 15 are elastically slidably connected to the surface of the cleaning rod 14 near the filter plate 7.

[0042] The drive mechanism includes multiple support plates 16, which are fixedly connected to the upper end of the fixed block 12. The support plates 16 are located on both sides of the rack 13. A rotating rod 17 is rotatably connected between the support plates 16 on both sides of the rack 13. The rotating rod 17 passes through the support plates 16. A first gear 18 is fixedly connected to the surface of the rotating rod 17 at the middle position of the two support plates 16. The first gear 18 meshes with the rack 13. A second gear 19 is fixedly connected to the surface of the rotating rod 17 near the main beam 2. The upper end of the support base 1 and the front and rear sides of the upper end of the pressure plate 6 are both fixedly connected to the drive rail 20. The second gear 19 is located inside the drive rail 20. Part of the drive teeth 21 are fixedly connected to the bottom of the drive rail 20 near the pressure plate 6 and the upper part near the support base 1. The drive teeth 21 can act on the second gear 19.

[0043] The switching mechanism includes two switching plates 22, which are fixedly connected to the front and rear sides of the upper end of the support base 1 and the upper end of the pressing plate 6, respectively. The surface of the switching plate 22 is provided with a switching groove 23, and the middle position of the switching groove 23 is an inclined groove. The rotating rod 17 is located in the switching groove 23. The support plate 16 is provided with a through groove 24 corresponding to the position of the rotating rod 17.

[0044] The separation mechanism includes a mounting rod 25, which is fixedly connected to the upper end of the filter cloth 10. The side of the mounting rod 25 near the filter plate 7 is inclined, and an arc-shaped groove 26 is formed on the surface of the mounting rod 25 near the filter plate 7. The filter plate 7 has a mounting groove 27 corresponding to the position of the mounting rod 25. The bottom part of the mounting groove 27 is inclined, and the mounting rod 25 is located in the mounting groove 27. A separation plate 28 is slidably connected between the corresponding racks 13 on the front and rear sides. The part of the separation plate 28 corresponding to the position of the mounting groove 27 extends downward. The bottom of the separation plate 28 is inclined, and the surface of the separation plate 28 is... A separation groove 29 is provided, which penetrates the separation plate 28 and has an arc-shaped bottom. A push plate 30 is elastically connected to the upper end of the separation plate 28 and extends into the separation groove 29. An arc-shaped snap-fit ​​plate 31 is hinged to the bottom of the push plate 30 and can engage with the snap-fit ​​groove 26. The side of the push plate 30 away from the separation groove 29 slides between the corresponding racks 13 on the front and rear sides. A pressure rod 32 is elastically slidably connected to the middle position between the corresponding racks 13 on the front and rear sides through a gas spring. The pressure rod 32 can act on the push plate 30.

[0045] During the pressure filtration of organosilicon, the filter plates 7 are pressed together by the hydraulic cylinder 5. The organosilicon to be filtered is introduced through the connection port 4 and flows through the connecting port 8 to the spaces between multiple filter plates 7. Subsequently, gas is introduced between the filter plates 7 through the through hole 9 to dry the filter cake. After the pressure filtration is completed, the external controller controls the drive block 11 to open the filter plates 7 one by one. As the filter plates 7 move, the filter cake between them falls off. The movement of the filter plates 7 will drive the fixed block 12, rack 13, support plate 16, and rotating rod 17 to move together. The rotating rod 17 moves within the switching groove 23, which in turn drives the first gear 18 and the second gear 19 to move together. The second gear 19 moves within the drive rail 20. When the second gear 19 moves to the drive rail 20, the first gear 18 moves with the second gear 19. When tooth 21 is in position, drive tooth 21 will cause the second gear 19 to rotate. The second gear 19 will drive the rotating rod 17 and the first gear 18 to rotate. The first gear 18 will cause the rack 13 to move downward. The movement of rack 13 will cause the cleaning rod 14, the separating plate 28, the pushing plate 30 and the pressure rod 32 to move together. The separating plate 28 will move into the mounting groove 27. When the bottom of the separating plate 28 contacts the mounting rod 25, the rack 13 continues to move downward. The separating plate 28 will slide between the racks 13. Then the pressure rod 32 will move above the pushing plate and press down on the pushing plate 30. The pressing plate will move downward. The snap-fit ​​plate 31 will move out of the separating groove 29 under the action of the pressing plate and move into the snap-fit ​​groove 26. Then the separating plate When the separating plate 28 moves to the bottom of the mounting groove 27, the mounting groove 27 will cause the separating plate 28 to move a certain distance away from the filter plate 7, which helps to separate the filter cloth 10 from the filter plate 7. The filter residue attached to the surface of the filter cloth 10 can be separated from the filter plate 7, which is convenient for subsequent cleaning. This avoids the filter cloth 10 sticking to the filter plate 7 during cleaning, as the filter residue will stick tightly to the surface of the filter cloth 10 and the filter plate 7 during filtration, making it difficult to clean. Then the rack 13 continues to move downward, and the separating rod and the mounting plate will be in the mounting groove 27. When the cleaning rod 14 moves downward to the position of the filter cloth 10, the scraping block 15 will scrape off the filter residue on the surface of the filter cloth 10. This is beneficial for cleaning the filter residue remaining on the surface of the filter cloth 10 after one filtration, and prevents the residual filter residue from affecting the filter. The filtration effect of cloth 10 leads to a decrease in subsequent filtration efficiency. When the cleaning rod 14 moves to the bottom of the filter plate 7, the second gear 19 will move out of the position of the bottom drive tooth 21. Then, the rotating rod 17 will move to the inclined groove position of the switching groove 23. The rotating rod 17 will drive the second gear 19 to move upward. Then, the second gear 19 can mesh with the drive tooth 21 at the upper end of the drive rail 20. The rack 13 will drive the cleaning rod 14 to move upward, thereby returning to its original position. The switching mechanism and the drive mechanism can clean the filter cloth 10 by using the cleaning rod 14 during the movement of the filter plate 7, eliminating the need for manual cleaning, reducing the workload, and improving filtration efficiency. During subsequent pressure filtration, the drive block 11 pushes the multiple filter plates 7 back to the side close to the thrust plate 3.Hydraulic cylinder 5 pushes the clamping plate 6 again to press the filter plate 7 firmly.

[0046] During the cleaning process of the filter cloth 10, the scraping block 15 cannot remove the small filter residues adhering to the surface of the filter cloth 10. As a further solution of the present invention, an arc-shaped groove 33 is formed on the surface of the cleaning rod 14 near the filter cloth 10. A rotating shaft 34 is rotatably connected inside the groove 33, and the rotating shaft 34 passes through the cleaning rod 14. Multiple soft actuating rods 35 are fixedly connected to the surface of the cleaning rod 14 located inside the groove 33. A rotating column 36 is rotatably connected to the upper end of the surface of the rack 13. Multiple fixing plates 37 are fixedly connected to the surface of the fixing block 12. A tensioning column 38 is elastically rotatably connected to the surface of the fixing plate 37 through a gas spring. A transmission belt 39 is connected to the surface of the rotating rod 17, the surface of the tensioning column 38, the surface of the rotating column 36, and the surface of the rotating shaft 34. During the cleaning process of filter cloth 10, the drive gear 21 will act on the second gear 19 to rotate together with the rotating rod 17. The rotating rod 17 will drive the tensioning column 38, the rotating column 36 and the rotating shaft 34 to rotate through the transmission belt 39. The actuating rod 35 on the surface of the rotating shaft 34 will tap the surface of the filter cloth 10, which is beneficial to cleaning the smaller filter residues attached to the surface of the filter cloth 10, ensuring the filtration effect of the filter cloth 10, and preventing the scraping block 15 from leaving smaller filter residues that cannot be cleaned when scraping the larger filter residues on the surface of the filter cloth 10, thereby affecting the filtration effect of the filter cloth 10 and reducing the filtration efficiency. The tensioning column 38 can make the transmission belt 39 fit with the surface of the rotating rod 17, the surface of the tensioning column 38, the surface of the rotating column 36 and the surface of the rotating shaft 34, preventing the transmission belt 39 from detaching.

[0047] When cleaning the filter cloth 10, relatively wet filter residue will stick to the surface of the filter cloth 10. As a further embodiment of the present invention, a brush 40 is fixedly connected to the surface of the cleaning rod 14. During the cleaning process of the filter cloth 10, the cleaning brush can remove the filter residue sticking to the surface of the filter cloth 10, ensuring the cleaning effect of the filter cloth 10 and improving the filtration efficiency.

[0048] A smart pressure filtration process suitable for organosilicon, the specific steps of which are as follows:

[0049] Step 1: Before pressing the organosilicon, the filter press device needs to be started first. The hydraulic cylinder 5 will press the multiple filter plates 7 together.

[0050] Step 2: Then, the silicone to be filtered is introduced into the filter plate 7 through the connection port 4. The silicone will gradually fill the depressions between the filter plates 7.

[0051] Step 3: Then, gas is introduced into it through the through hole 9, and the moisture in the organosilicon will flow out;

[0052] Step 4: After the filter press is completed, when the filter plate 7 is opened, the cleaning mechanism will clean the surface of the filter cloth 10 under the action of the drive mechanism;

[0053] Step 5: During the cleaning process, the separation mechanism will separate the filter cloth 10 from the filter plate 7, making it easier to clean the filter residue;

[0054] Step Six: Switching the mechanism will then restore the cleaning mechanism to its original position.

Claims

1. A smart filter press device suitable for organosilicon, comprising a support base (1), characterized in that: The support base (1) is fixedly connected to the front and rear ends of the main beam (2). A thrust plate (3) is fixedly connected between the two main beams (2) on the side away from the support base (1). A connection port (4) is opened in the middle of the thrust plate (3). A hydraulic cylinder (5) is fixedly connected to the surface of the support base (1) on the side away from the thrust plate (3). A clamping plate (6) is fixedly connected through the hydraulic cylinder (5) through the rear end of the support base (1). The clamping plate (6) slides between the two main beams (2). Multiple filter plates (7) are slidably connected between the two main beams (2). A connecting port (8) is opened in the middle of the multiple filter plates (7). Through holes (9) are opened at the four corners of the surface of the filter plates (7). There are recesses in the middle part of both sides of the filter plates (7). The filter plate (7) is connected to the through hole (9). Filter cloth (10) is provided at the corresponding recessed positions on both sides of the filter plate (7). A drive block (11) is slidably connected to the surface of the main beam (2). The drive block (11) is controlled by an external driver. A cleaning mechanism is provided at the upper end of the filter plate (7). The cleaning mechanism can clean the residual filter residue on the surface of the filter cloth (10). A drive mechanism is provided above the thrust plate (3). The drive mechanism can drive the cleaning mechanism to move up and down for cleaning. A switching mechanism is provided on one side of the drive mechanism. The switching mechanism can switch to moving up after the cleaning mechanism has finished cleaning the filter cloth (10) downwards. A separation mechanism is provided on the surface of the filter plate (7). The separation mechanism can separate the filter cloth (10) from the filter plate (7) before the cleaning mechanism cleans. The cleaning mechanism includes two fixed blocks (12), which are fixedly connected to the front and rear sides of the upper end of the filter plate (7) respectively. Both sides of the two fixed blocks (12) are slidably connected to racks (13). The bottom of the two racks (13) on the same side is fixedly connected to a cleaning rod (14). Multiple scraping blocks (15) are elastically slidably connected to the surface of the cleaning rod (14) near the filter plate (7). The separation mechanism includes an installation rod (25), which is fixedly connected to the upper end of the filter cloth (10). The side of the installation rod (25) near the filter plate (7) is inclined, and an arc-shaped groove (26) is opened on the surface of the installation rod (25) near the filter plate (7). The filter plate (7) has an installation groove (27) corresponding to the position of the installation rod (25). The bottom part of the installation groove (27) is inclined, and the installation rod (25) is located in the installation groove (27). A separation plate (28) is slidably connected between the corresponding racks (13) on the front and rear sides. The part of the separation plate (28) corresponding to the position of the installation groove (27) extends downward. The bottom of the separation plate (28) is inclined, and the separation plate (28) is slidably connected between the corresponding racks (13) on the front and rear sides. 8) A separation groove (29) is provided on the surface. The separation groove (29) penetrates the separation plate (28) and the bottom of the separation groove (29) is arc-shaped. A push plate (30) is elastically connected to the upper end of the separation plate (28). The push plate (30) extends into the separation groove (29). An arc-shaped snap-fit ​​plate (31) is hinged to the bottom of the push plate (30). The snap-fit ​​plate (31) can engage with the snap-fit ​​groove (26). The push plate (30) slides between the corresponding racks (13) on the front and rear sides on the side away from the separation groove (29). The middle position between the corresponding racks (13) on the front and rear sides is elastically slidably connected to a pressure rod (32) by a gas spring. The pressure rod (32) can act on the push plate (30).

2. The intelligent filter press device suitable for organosilicon according to claim 1, characterized in that: The driving mechanism includes multiple support plates (16), which are fixedly connected to the upper end of the fixed block (12). The support plates (16) are located on both sides of the rack (13). A rotating rod (17) is rotatably connected between the support plates (16) on both sides of the rack (13). The rotating rod (17) passes through the support plates (16). A first gear (18) is fixedly connected to the surface of the rotating rod (17) at the middle position of the two support plates (16). The first gear (18) and the rack (13) are connected... The rotating rod (17) is fixedly connected to a second gear (19) on the surface near the main beam (2). The upper end of the support base (1) and the front and rear sides of the upper end of the pressure plate (6) are both fixedly connected to a drive rail (20). The second gear (19) is located inside the drive rail (20). The bottom of the drive rail (20) near the pressure plate (6) and the upper part near the support base (1) are both fixedly connected to a portion of the drive teeth (21). The drive teeth (21) can act on the second gear (19).

3. The intelligent pressure filter device suitable for organosilicon according to claim 2, characterized in that: The switching mechanism includes two switching plates (22), which are fixedly connected to the front and rear sides of the upper end of the support base (1) and the upper end of the pressing plate (6), respectively. The surface of the switching plate (22) is provided with a switching groove (23), and the middle position of the switching groove (23) is an inclined groove. The rotating rod (17) is located in the switching groove (23). The support plate (16) is provided with a through groove (24) corresponding to the position of the rotating rod (17).

4. The intelligent pressure filter device suitable for organosilicon according to claim 2, characterized in that: The cleaning rod (14) has an arc-shaped groove (33) on the side near the filter cloth (10). A rotating shaft (34) is rotatably connected inside the groove (33). The rotating shaft (34) passes through the cleaning rod (14). Multiple soft actuating rods (35) are fixedly connected to the surface of the cleaning rod (14) inside the groove (33). A rotating column (36) is rotatably connected to the upper end of the surface of the rack (13). Multiple fixing plates (37) are fixedly connected to the surface of the fixing block (12). A tensioning column (38) is elastically rotatably connected to the surface of the fixing plate (37) through a gas spring. A transmission belt (39) is connected to the surface of the rotating rod (17), the surface of the tensioning column (38), the surface of the rotating column (36), and the surface of the rotating shaft (34).

5. The intelligent filter press device suitable for organosilicon according to claim 1, characterized in that: A brush (40) is fixedly connected to the surface of the cleaning rod (14).

6. A smart pressure filtration process suitable for organosilicon, applicable to the smart pressure filtration device suitable for organosilicon as described in any one of claims 1-5, characterized in that: The specific steps of this process are as follows: Step 1: Before pressing the organosilicon, the filter press device needs to be started first. The hydraulic cylinder (5) will press the multiple filter plates (7) together. Step 2: Then, the organosilicon to be filtered is introduced into the filter plate (7) through the connection port (4). The organosilicon will gradually fill the depressions between the filter plates (7). Step 3: Then gas is introduced into it through the through hole (9), and the moisture in the organosilicon will flow out; Step 4: After the filter press is completed, when the filter plate (7) is opened, the cleaning mechanism will clean the surface of the filter cloth (10) under the action of the drive mechanism; Step 5: During the cleaning process, the separation mechanism will separate the filter cloth (10) from the filter plate (7), which facilitates the cleaning of the filter residue; Step Six: Switching the mechanism will then restore the cleaning mechanism to its original position.