Power battery material intelligent cleaning and drying integrated equipment group

By designing an integrated intelligent cleaning and drying equipment for power battery materials, the fully automated circulation and clean production of power battery materials have been achieved, solving the problems of large footprint, serious pollution, and resource waste associated with traditional equipment, and improving production efficiency and environmental friendliness.

CN224389489UActive Publication Date: 2026-06-23JINHUASHENG (SHENZHEN) TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JINHUASHENG (SHENZHEN) TECHNOLOGY CO LTD
Filing Date
2025-07-17
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Traditional power battery material cleaning and drying equipment is independent and decentralized, occupies a large area, is prone to contamination during material transfer, has low cleaning efficiency, cannot recycle cleaning fluid, and wastes resources seriously, making it difficult to meet the needs of high-quality production.

Method used

The design incorporates an integrated intelligent cleaning and drying equipment for power battery materials, including a stirring and cleaning unit, a diaphragm isolation and cleaning component, and a drying component. The entire process is automated through a plate chain conveyor mechanism. It employs multi-stage filtration and recycling of the cleaning solution, combined with three-stage diaphragm isolation and drying technology, to achieve fully automated continuous production.

Benefits of technology

It significantly improved production efficiency, reduced material loss and secondary pollution, saved water and electricity resources, and achieved clean production and energy conservation and environmental protection.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The utility model provides power battery material intelligent cleaning drying integration equipment group, including main part assembly, the main part assembly includes stirring cleaning unit, diaphragm isolation cleaning subassembly and drying assembly, the utility model discloses through the plate chain conveying mechanism series connection into the continuous production line, and the material is dispersed cleaning, diaphragm separation and drying three major processes in turn, and the material need not midway transfer, and the whole process automation flow transfer from the cleaning pool to the drying pool through the diaphragm isolation pool, effectively avoid the material loss and secondary pollution in traditional segmented processing, and, realize full -automatic continuous production, and the production efficiency has been improved greatly, through the cleaning stirring device to the material dispersed cleaning, and through the diaphragm isolation device adopts three -level isolation to the diaphragm in material and separates, thereby the cleaning effect has been improved significantly, simultaneously through the coarse filter pool, ceramic filter and so on multistage filtration to the cleaning fluid filtration and recycling use, significantly reduced the consumption of water, electricity and so on resources, realized energy -conserving and environment -protecting.
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Description

Technical Field

[0001] This utility model relates to the field of power battery production equipment technology, and in particular to an integrated intelligent cleaning and drying equipment group for power battery materials. Background Technology

[0002] With the rapid development of the new energy industry, the market demand for power batteries, as a core component, is experiencing explosive growth. The performance of power batteries largely depends on the meticulous control of each stage of the production process, among which the cleaning and drying of power battery materials plays a crucial role.

[0003] Traditional cleaning and drying equipment is often independent and decentralized, resulting in large floor space, easy contamination during material transfer, and low cleaning efficiency. At the same time, the cleaning effect is poor in the material decentralized cleaning process, the cleaning solution cannot be recycled, and there is serious waste of resources, making it difficult to meet the needs of high-quality production. Therefore, an integrated intelligent cleaning and drying equipment for power battery materials is proposed. Utility Model Content

[0004] In view of this, the present invention aims to provide an integrated intelligent cleaning and drying equipment for power battery materials to solve or alleviate the technical problems existing in the prior art, and at least provide a beneficial option.

[0005] The technical solution of this utility model embodiment is implemented as follows: an integrated intelligent cleaning and drying equipment group for power battery materials, including a main component, wherein the main component includes a stirring and cleaning unit, a diaphragm isolation and cleaning unit, and a drying unit;

[0006] A diaphragm isolation cleaning component is installed at one end of the mixing and cleaning unit, and a drying component is installed at the end of the diaphragm isolation cleaning component away from the mixing and cleaning unit.

[0007] The stirring and cleaning unit includes two stirring and cleaning components, which are fixedly connected in sequence.

[0008] More preferably, the stirring and cleaning assembly includes a cleaning and stirring device, a cleaning tank, a first spiral conveying mechanism, a first coarse filter tank, a first connecting pipe, a first water pump, a second connecting pipe, a first ceramic filter, a first water outlet pipe, a first sewage discharge pipe, a first support base, a first bracket, a first clean water collection tank, a first sedimentation tank, a third connecting pipe, a second water pump, and a fourth connecting pipe.

[0009] The cleaning tank is equipped with a cleaning and stirring device. A first spiral conveying mechanism is located at the bottom of the cleaning tank. The discharge end of the first spiral conveying mechanism is connected to a first coarse filter. A first water pump is connected to the bottom center of the first coarse filter via a first connecting pipe. The liquid outlet of the first water pump is connected to a first ceramic filter via a second connecting pipe. A first water outlet pipe is located on the upper side of the outer wall of the first ceramic filter. A first sewage pipe is connected to the top of the first ceramic filter. A first support base is fixedly connected to the bottom outer side of the first coarse filter. A first clean water collection tank is fixedly connected to the upper surface of the first support base near the first water outlet pipe via a first bracket. A first sedimentation tank is fixedly connected to the upper surface of the first support base away from the first water outlet pipe. The liquid outlet of the first sewage pipe is connected to the top of the first sedimentation tank. A second water pump is connected to the bottom center of both the first clean water collection tank and the first coarse filter via a third connecting pipe. The water outlets of both second water pumps are connected to the upper side of the front surface of the cleaning tank via a fourth connecting pipe.

[0010] More preferably, the diaphragm isolation cleaning assembly includes a diaphragm isolation tank, a diaphragm isolation device, a stirring mechanism, a second spiral conveying mechanism, a second coarse filter tank, a fifth connecting pipe, a third water pump, a sixth connecting pipe, a second ceramic filter, a second water outlet pipe, a second sewage discharge pipe, a second support base, a second bracket, a second clean water collection tank, a second sedimentation tank, a seventh connecting pipe, a fourth water pump, and an eighth connecting pipe.

[0011] A diaphragm isolation device is installed in the middle of the inner wall of the diaphragm isolation tank. A stirring mechanism is installed on both sides of the inner wall of the diaphragm isolation device. A second spiral conveying mechanism is installed at the bottom of the washing tank. The discharge end of the second spiral conveying mechanism is connected to a second coarse filter. A third water pump is connected to the bottom center of the second coarse filter via a fifth connecting pipe. The liquid outlet of the third water pump is connected to a second ceramic filter via a sixth connecting pipe. A second water outlet pipe is installed on the upper side of the outer wall of the second ceramic filter. A second sewage discharge pipe is connected to the top of the second ceramic filter. The second coarse filter tank is fixedly connected to a second support base on the outer bottom of the second coarse filter tank. A second clear water collection tank is fixedly connected to the upper surface of the second support base near the second outlet pipe via a second bracket. A second sedimentation tank is fixedly connected to the upper surface of the second support base away from the second outlet pipe. The outlet end of the second sewage pipe is connected to the top of the second sedimentation tank. A fourth water pump is connected to the bottom center of both the second clear water collection tank and the second coarse filter tank via a seventh connecting pipe. The outlet ends of both fourth water pumps are connected to the upper part of the front surface of the diaphragm isolation tank via an eighth connecting pipe.

[0012] More preferably, the drying assembly includes a drying tank, a drying frame, a drying cover, a heating element, and a fan mechanism;

[0013] A drying rack is fixedly connected to the top of the outer wall of the drying tank, and a drying cover is fixedly connected to the top of the drying rack. A heating tube is installed inside the drying cover, and a fan mechanism is installed on both sides of the upper surface of the drying cover.

[0014] More preferably, a support frame is fixedly connected to the top of the outer side wall of both the washing tank and the diaphragm isolation tank, and a plate chain conveyor mechanism is provided on the lower part of the inner side wall of both the support frame and the drying frame.

[0015] More preferably, a feeder is installed at the end of the mixing and cleaning unit away from the diaphragm isolation cleaning component.

[0016] More preferably, a feeder is installed at the end of the drying assembly away from the diaphragm isolation cleaning assembly.

[0017] More preferably, a protective cover is fixedly connected to the top of the support frame.

[0018] The present invention has the following advantages due to the adoption of the above technical solution:

[0019] 1. This utility model uses a plate chain conveyor mechanism to connect the three major processes of material dispersion cleaning, diaphragm separation and drying in sequence. The material does not need to be transferred in the middle. It flows automatically from the cleaning tank through the diaphragm separation tank to the drying tank. This effectively avoids material loss and secondary pollution in traditional segmented processing. At the same time, it realizes fully automated continuous production and greatly improves production efficiency.

[0020] 2. This utility model disperses and cleans materials through a cleaning and stirring device, and separates the membranes in the materials through a three-stage diaphragm isolation device, thereby significantly improving the cleaning effect. At the same time, the cleaning solution is filtered and recycled through multi-stage filtration such as a coarse filter and a ceramic filter, which significantly reduces the consumption of water, electricity and other resources, and achieves energy conservation and environmental protection.

[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 an overall structural diagram of the present invention;

[0024] Figure 2 This is a structural diagram of the stirring and cleaning component of this utility model;

[0025] Figure 3 This utility model Figure 2 Another perspective on the structure diagram;

[0026] Figure 4 This is a structural diagram of the cleaning tank and cleaning stirring device of this utility model;

[0027] Figure 5 This is a structural diagram of the diaphragm isolation and cleaning assembly of this utility model;

[0028] Figure 6 This utility model Figure 5 Another perspective on the structure diagram;

[0029] Figure 7 This is a structural diagram of the diaphragm isolation pool and diaphragm isolation device of this utility model;

[0030] Figure 8 This is a structural diagram of the drying component of this utility model.

[0031] Reference numerals: 1. Main component; 11. Mixing and cleaning unit; 12. Diaphragm isolation and cleaning component; 14. Drying component; 15. Mixing and cleaning component; 17. Diaphragm isolation tank; 18. Diaphragm isolation device; 19. Mixing mechanism; 20. Second screw conveyor mechanism; 21. Second coarse filter tank; 22. Fifth connecting pipe; 23. Third water pump; 24. Sixth connecting pipe; 25. Second ceramic filter; 26. Second outlet pipe; 27. Second sewage pipe; 28. Second support base; 29. ​​Second bracket; 30. Second clear water collection tank; 31. Second sedimentation tank; 32. Seventh connecting pipe; 33. Fourth water pump; 34. Eighth connecting pipe; 41. Drying tank; 42. Drying frame; 43. Drying cover; 44. Heating element; 45. Fan mechanism; 50. Cleaning and stirring device; 51. Cleaning tank; 52. First screw conveyor mechanism; 53. First coarse filter tank; 54. First connecting pipe; 55. First water pump; 56. Second connecting pipe; 57. First ceramic filter; 58. First water outlet pipe; 59. First sewage discharge pipe; 60. First support base; 61. First bracket; 62. First clear water collection tank; 63. First sedimentation tank; 64. Third connecting pipe; 65. Second water pump; 66. Fourth connecting pipe; 67. Support frame; 68. Plate chain conveyor mechanism; 69. Feeder; 70. Discharger; 71. Protective cover. Detailed Implementation

[0032] 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.

[0033] The embodiments of this utility model will now be described in detail with reference to the accompanying drawings.

[0034] like Figures 1-8 As shown, the present invention provides an integrated intelligent cleaning and drying equipment group for power battery materials, including a main component 1, which includes a stirring and cleaning unit 11, a diaphragm isolation and cleaning component 12, and a drying component 14.

[0035] A diaphragm isolation cleaning component 12 is installed at one end of the mixing and cleaning unit 11, and a drying component 14 is installed at the end of the diaphragm isolation cleaning component 12 that is away from the mixing and cleaning unit 11.

[0036] The stirring and cleaning unit 11 includes two stirring and cleaning components 15, which are fixedly connected in sequence. The two sets of stirring and cleaning components 15 stir and clean the material, thereby completely removing impurities from the material surface. The diaphragm isolation cleaning component 12 isolates the diaphragm floating in the material, allowing the copper foil and aluminum foil materials to flow away under the isolation plate, thus facilitating the cleaning of the diaphragm in the material.

[0037] In one embodiment, the stirring and cleaning assembly 15 specifically includes a cleaning and stirring device 50, a cleaning tank 51, a first spiral conveying mechanism 52, a first coarse filter tank 53, a first connecting pipe 54, a first water pump 55, a second connecting pipe 56, a first ceramic filter 57, a first water outlet pipe 58, a first sewage discharge pipe 59, a first support base 60, a first bracket 61, a first clean water collection tank 62, a first sedimentation tank 63, a third connecting pipe 64, a second water pump 65, and a fourth connecting pipe 66.

[0038] The cleaning tank 51 is equipped with a cleaning and stirring device 50. A first spiral conveying mechanism 52 is located at the bottom of the cleaning tank 51. The discharge end of the first spiral conveying mechanism 52 is connected to a first coarse filter tank 53. A first water pump 55 is connected to the bottom center of the first coarse filter tank 53 via a first connecting pipe 54. The liquid outlet end of the first water pump 55 is connected to a first ceramic filter 57 via a second connecting pipe 56. A first water outlet pipe 58 is located on the upper side of the outer wall of the first ceramic filter 57. A first sewage pipe 59 is connected to the top of the first ceramic filter 57. A first support base 60 is fixedly connected to the bottom outer side of the first coarse filter tank 53. A first clean water collection tank 62 is fixedly connected to the upper surface of the first support base 60 near the first water outlet pipe 58 via a first bracket 61. A first clean water collection tank 62 is fixedly connected to the upper surface of the first support base 60 away from the first water outlet pipe 58. A sedimentation tank 63 is provided, with the outlet end of the first sewage pipe 59 connected to the top of the first sedimentation tank 63. The bottom center of the first clear water collection tank 62 and the first coarse filter tank 53 are both connected to a second water pump 65 via a third connecting pipe 64. The outlet ends of the two second water pumps 65 are both connected to the upper part of the front surface of the cleaning tank 51 via a fourth connecting pipe 66. The cleaning and stirring device 50 includes a stirring motor, a stirring shaft, and stirring blades. The stirring motor drives the stirring shaft to rotate, thereby driving the stirring blades to rotate. The stirring blades rotate in a propeller manner, which facilitates the dispersion and cleaning of the product, dispersing the product into copper foil, aluminum foil, diaphragm, and graphite. In addition, a water temperature heater is also provided inside the cleaning tank 51 to heat the cleaning liquid in the cleaning tank 51. The water temperature heater heats the cleaning liquid to 100°C, which facilitates the removal of black powder from the surface of the material.

[0039] The first spiral conveying mechanism 52 facilitates the transport of impurities settled at the bottom of the washing tank 51 to the first coarse filter tank 53, initially separating some impurities and reducing the burden on subsequent filtration. The bottom center of the first coarse filter tank 53 is connected to a first water pump 55 via a first connecting pipe 54. After the first water pump 55 starts, it extracts the washing liquid from the first coarse filter tank 53 and transports it to the first ceramic filter 57 via a second connecting pipe 56. The first ceramic filter 57 can perform high-precision filtration of the washing liquid, effectively removing fine particulate impurities and additives. The filtered pure washing liquid flows from the upper part of the outer wall of the first ceramic filter 57. The first water outlet pipe 58 on one side flows out and into the first clean water collection tank 62 for storage, to be used in subsequent production; during the filtration process of the first ceramic filter 57, the unfiltered wastewater is discharged into the first sedimentation tank 63 through the first sewage pipe 59 connected to the top of the first ceramic filter 57, and is filtered again inside the first sedimentation tank 63 to further separate any possible residual small particles, preventing them from polluting the environment or clogging the pipes; after the second water pump 65 is started, the liquid in the first clean water collection tank 62 and the first sedimentation tank 63 is transported back to the cleaning tank 51 through the fourth connecting pipe 66, realizing the recycling of the cleaning liquid.

[0040] In one embodiment, specifically: the diaphragm isolation cleaning assembly 12 includes a diaphragm isolation tank 17, a diaphragm isolation device 18, a stirring mechanism 19, a second spiral conveying mechanism 20, a second coarse filter tank 21, a fifth connecting pipe 22, a third water pump 23, a sixth connecting pipe 24, a second ceramic filter 25, a second water outlet pipe 26, a second sewage discharge pipe 27, a second support base 28, a second bracket 29, a second clean water collection tank 30, a second sedimentation tank 31, a seventh connecting pipe 32, a fourth water pump 33, and an eighth connecting pipe 34;

[0041] A diaphragm isolation device 18 is installed in the middle of the inner wall of the diaphragm isolation tank 17. A stirring mechanism 19 is installed on both sides of the inner wall of the diaphragm isolation tank 17 near the diaphragm isolation device 18. A second spiral conveying mechanism 20 is installed at the bottom of the washing tank 51. The discharge end of the second spiral conveying mechanism 20 is connected to a second coarse filter tank 21. A third water pump 23 is connected to the bottom center of the second coarse filter tank 21 via a fifth connecting pipe 22. The liquid outlet end of the third water pump 23 is connected to a second ceramic filter 25 via a sixth connecting pipe 24. A second water outlet pipe 26 is installed on one side of the upper outer wall of the second ceramic filter 25. A second sewage pipe 27 is connected to the top of the second ceramic filter 25. A second support base 28 is fixedly connected to the bottom outer side of the second coarse filter tank 21. A second clear water collection tank 30 is fixedly connected to the side of the upper surface of the second support base 28 near the second outlet pipe 26 via a second bracket 29. A second sedimentation tank 31 is fixedly connected to the side of the upper surface of the second support base 28 away from the second outlet pipe 26. The liquid outlet end of the second sewage pipe 27 is connected to the top of the second sedimentation tank 31. A fourth water pump 33 is connected to the bottom center of both the second clear water collection tank 30 and the second coarse filter tank 21 via a seventh connecting pipe 32. The water outlet ends of both fourth water pumps 33 are connected to the upper part of the front surface of the diaphragm isolation tank 17 via an eighth connecting pipe 34.

[0042] The diaphragm isolation device 18 uses a three-stage isolation method to isolate and clean the diaphragm floating in the diaphragm isolation pool 17. The stirring mechanisms 19 on both sides of the diaphragm isolation device 18 are used to stir and clean the dispersed copper foil and aluminum foil, so that the graphite on the copper foil and aluminum foil can be completely removed.

[0043] The cleaning solution in the diaphragm isolation tank 17 is also recycled, and the filtration method is the same as that of the cleaning solution in the cleaning tank 51.

[0044] In one embodiment, the drying assembly 14 specifically includes a drying tank 41, a drying frame 42, a drying cover 43, a heating element 44, and a fan mechanism 45.

[0045] A drying rack 42 is fixedly connected to the top of the outer wall of the drying tank 41. A drying cover 43 is fixedly connected to the top of the drying rack 42. A heating tube 44 is installed inside the drying cover 43. A fan mechanism 45 is installed on both sides of the upper surface of the drying cover 43. After cleaning, the material enters the drying tank 41 of the drying assembly 14. The heating tube 44 generates radiant heat inside the drying cover 43. At the same time, the fan mechanism 45 on both sides rotates at high speed, distributing the heat evenly to all areas of the tank, avoiding local overheating of the material and improving drying efficiency.

[0046] In one embodiment, specifically: a support frame 67 is fixedly connected to the top of the outer side wall of both the washing tank 51 and the diaphragm isolation tank 17, and a plate chain conveying mechanism 68 is provided on the lower part of the inner side wall of both the support frame 67 and the drying frame 42, so that the material can be continuously conveyed through the plate chain conveying mechanism 68.

[0047] In one embodiment, specifically: a feeder 69 is installed at one end of the mixing and cleaning unit 11 away from the diaphragm isolation cleaning component 12, through which the material is conveniently conveyed to the plate chain conveyor mechanism 68.

[0048] In one embodiment, specifically: a feeder 70 is installed at one end of the drying assembly 14 away from the diaphragm isolation cleaning assembly 12. The feeder 70 facilitates the feeding of the dried material from the plate chain conveyor 68 to subsequent processing equipment (such as a vibrating screen) for further processing.

[0049] In one embodiment, specifically: a protective cover 71 is fixedly connected to the top of the support frame 67, which facilitates the protection of the top of the cleaning tank 51 and the diaphragm isolation tank 17, preventing dust and impurities from entering and causing pollution.

[0050] In operation, the power battery material to be processed is conveyed by the feeder 69 to the plate chain conveyor 68 of the supporting frame 67 and enters the cleaning tank 51 of the stirring and cleaning unit 11. The cleaning and stirring device 50 rotates in a propeller manner to disperse the material into copper foil, aluminum foil, separator and graphite. At the same time, the water heater heats the water to 100°C to remove black powder from the surface of the material. The first spiral conveyor 52 sends the precipitated impurities into the first coarse filter tank 53. After the cleaning liquid is drawn by the first water pump 55 and filtered by the first ceramic filter 57, the pure liquid flows into the first clear water collection tank 62, and the unfiltered wastewater is discharged into the first sedimentation tank 63. Both are circulated back to the cleaning tank 51 by the second water pump 65. The material that has been preliminarily cleaned is conveyed by the plate chain. Mechanism 68 enters the diaphragm isolation tank 17 of the diaphragm isolation cleaning assembly 12. The diaphragm isolation device 18 adopts three-stage isolation, so that the diaphragm floats on the water surface and the copper foil and aluminum foil flow away under the isolation plate. The stirring mechanisms 19 on both sides further clean the material to remove the graphite. The second spiral conveying mechanism 20 sends the impurities into the second coarse filter tank 21, and the cleaning liquid is recycled in the same filtration method. The cleaned material enters the drying tank 41 of the drying assembly 14. The heating tube 44 generates radiant heat, and the fan wheel mechanism 45 evenly distributes the heat to dry the material. The dried material is unloaded by the unloading machine 70 to complete the entire cleaning process. During the entire cleaning process, the protective cover 71 on the top of the support frame 67 prevents dust contamination, and the plate chain conveying mechanism 68 realizes continuous material transmission.

[0051] The above description is merely a specific embodiment of this utility model, but the protection scope of this utility model is not limited thereto. Any person skilled in the art can easily conceive of various variations or substitutions within the technical scope disclosed in this utility model, and these should all be included within the protection scope of this utility model. Therefore, the protection scope of this utility model should be determined by the protection scope of the claims.

Claims

1. An integrated intelligent cleaning and drying equipment for power battery materials, characterized in that: It includes a main component (1), which includes a stirring and cleaning unit (11), a diaphragm isolation and cleaning component (12), and a drying component (14); A diaphragm isolation cleaning component (12) is installed at one end of the stirring and cleaning unit (11), and a drying component (14) is installed at the end of the diaphragm isolation cleaning component (12) away from the stirring and cleaning unit (11). The stirring and cleaning unit (11) includes two stirring and cleaning components (15), which are fixedly connected in sequence.

2. The integrated intelligent cleaning and drying equipment for power battery materials according to claim 1, characterized in that: The stirring and cleaning assembly (15) includes a cleaning and stirring device (50), a cleaning tank (51), a first spiral conveying mechanism (52), a first coarse filter tank (53), a first connecting pipe (54), a first water pump (55), a second connecting pipe (56), a first ceramic filter (57), a first water outlet pipe (58), a first sewage pipe (59), a first support base (60), a first bracket (61), a first clean water collection tank (62), a first sedimentation tank (63), a third connecting pipe (64), a second water pump (65), and a fourth connecting pipe (66). The cleaning tank (51) is equipped with a cleaning and stirring device (50) inside. A first spiral conveying mechanism (52) is provided at the bottom of the cleaning tank (51). The discharge end of the first spiral conveying mechanism (52) is connected to a first coarse filter tank (53). A first water pump (55) is connected to the bottom center of the first coarse filter tank (53) through a first connecting pipe (54). The liquid outlet end of the first water pump (55) is connected to a first ceramic filter (57) through a second connecting pipe (56). A first water outlet pipe (58) is provided on one side of the upper part of the outer wall of the first ceramic filter (57). A first sewage pipe (59) is connected to the top of the first ceramic filter (57). The bottom outer side of the first coarse filter tank (53) is fixed. A first support base (60) is connected. The upper surface of the first support base (60) near the first water outlet pipe (58) is fixedly connected to a first clean water collection tank (62) via a first bracket (61). The upper surface of the first support base (60) away from the first water outlet pipe (58) is fixedly connected to a first sedimentation tank (63). The liquid outlet end of the first sewage pipe (59) is connected to the top of the first sedimentation tank (63). The bottom center of the first clean water collection tank (62) and the first coarse filter tank (53) are both connected to a second water pump (65) via a third connecting pipe (64). The water outlet ends of the two second water pumps (65) are both connected to the upper part of the front surface of the cleaning tank (51) via a fourth connecting pipe (66).

3. The integrated intelligent cleaning and drying equipment for power battery materials according to claim 2, characterized in that: The diaphragm isolation cleaning assembly (12) includes a diaphragm isolation tank (17), a diaphragm isolation device (18), a stirring mechanism (19), a second spiral conveying mechanism (20), a second coarse filter tank (21), a fifth connecting pipe (22), a third water pump (23), a sixth connecting pipe (24), a second ceramic filter (25), a second water outlet pipe (26), a second sewage pipe (27), a second support base (28), a second bracket (29), a second clean water collection tank (30), a second sedimentation tank (31), a seventh connecting pipe (32), a fourth water pump (33), and an eighth connecting pipe (34). A diaphragm isolation device (18) is provided in the middle of the inner wall of the diaphragm isolation tank (17). A stirring mechanism (19) is provided on both sides of the inner wall of the diaphragm isolation tank (17) near the diaphragm isolation device (18). A second spiral conveying mechanism (20) is provided at the bottom of the washing tank (51). The discharge end of the second spiral conveying mechanism (20) is connected to a second coarse filter tank (21). A third water pump (23) is connected to the bottom center of the second coarse filter tank (21) through a fifth connecting pipe (22). The liquid outlet end of the third water pump (23) is connected to a second ceramic filter (25) through a sixth connecting pipe (24). A second water outlet pipe (26) is provided on one side of the upper part of the outer wall of the second ceramic filter (25). A second sewage pipe is connected to the top of the second ceramic filter (25). 27), a second support base (28) is fixedly connected to the bottom outer side of the second coarse filter (21). A second clear water collection tank (30) is fixedly connected to the side of the upper surface of the second support base (28) near the second outlet pipe (26) via a second bracket (29). A second sedimentation tank (31) is fixedly connected to the side of the upper surface of the second support base (28) away from the second outlet pipe (26). The liquid outlet end of the second sewage pipe (27) is connected to the top of the second sedimentation tank (31). The bottom center of the second clear water collection tank (30) and the second coarse filter (21) are both connected to a fourth water pump (33) via a seventh connecting pipe (32). The water outlet ends of the two fourth water pumps (33) are both connected to the upper part of the front surface of the diaphragm isolation tank (17) via an eighth connecting pipe (34).

4. The integrated intelligent cleaning and drying equipment for power battery materials according to claim 3, characterized in that: The drying assembly (14) includes a drying tank (41), a drying frame (42), a drying cover (43), a heating element (44), and a fan mechanism (45); A drying rack (42) is fixedly connected to the top of the outer wall of the drying tank (41), and a drying cover (43) is fixedly connected to the top of the drying rack (42). A heating tube (44) is provided inside the drying cover (43), and a fan mechanism (45) is provided on both sides of the upper surface of the drying cover (43).

5. The integrated intelligent cleaning and drying equipment for power battery materials according to claim 4, characterized in that: The top of the outer side wall of the washing tank (51) and the diaphragm isolation tank (17) are fixedly connected to a support frame (67), and the lower part of the inner side wall of the support frame (67) and the drying frame (42) are provided with a plate chain conveyor mechanism (68).

6. The integrated intelligent cleaning and drying equipment for power battery materials according to claim 1, characterized in that: A feeder (69) is installed at the end of the mixing and cleaning unit (11) away from the diaphragm isolation cleaning component (12).

7. The integrated intelligent cleaning and drying equipment for power battery materials according to claim 6, characterized in that: A feeder (70) is installed at the end of the drying assembly (14) away from the diaphragm isolation cleaning assembly (12).

8. The integrated intelligent cleaning and drying equipment for power battery materials according to claim 5, characterized in that: A protective cover (71) is fixedly connected to the top of the support frame (67).