阅读说明：本技术 隔离式钢铁渣资源化用电极板上涂料线组 (Isolated iron and steel slag recycling electrode plate coating line group ) 是由 彭成才 于 2021-08-02 设计创作，主要内容包括：本发明涉及一种钢铁渣领域,尤其涉及一种隔离式钢铁渣资源化用电极板上涂料线组。本发明的技术问题为：提供一种隔离式钢铁渣资源化用电极板上涂料线组。一种隔离式钢铁渣资源化用电极板上涂料线组,包括有第一工作台、运输组件、涂层组件和清理组件等；涂层组件与清理组件进行固接。本发明使用时实现了自动使用波浪海绵块对电极板涂抹涂料,避免了普通海绵涂抹时被挤压而导致的涂抹不均匀的现象,同时自动对波浪海绵分隔后再注入涂料,避免了海绵块中高处的涂料向低处聚集的现象,还实现了自动将残留在电极板侧面的涂料清除干净,并避免了电极板上表面的涂料缺失的现象。(The invention relates to the field of steel slag, in particular to a coating line group on an electrode plate for recycling isolated steel slag. The technical problem of the invention is as follows: provides a coating line group on an electrode plate for recycling isolated iron and steel slag. A coating line group on an electrode plate for recycling isolated iron and steel slag comprises a first workbench, a transportation assembly, a coating assembly, a cleaning assembly and the like; the coating component is fixedly connected with the cleaning component. When the device is used, the automatic coating of the electrode plate by using the wave sponge block is realized, the phenomenon of uneven coating caused by extrusion when common sponge is coated is avoided, meanwhile, the coating is injected after the wave sponge block is automatically separated, the phenomenon that the coating at the high position in the sponge block is gathered to the low position is avoided, the automatic cleaning of the coating remained on the side surface of the electrode plate is realized, and the phenomenon that the coating on the upper surface of the electrode plate is lost is avoided.)

1. An isolated electrode plate coating line group for recycling steel and iron slag comprises a first workbench (1), a second workbench (2), a third workbench (3), a first connecting block (4), a second connecting block (5), a third connecting block (6), a fourth connecting block (7) and a first electrode plate (8); the first workbench (1) is fixedly connected with the second workbench (2); the upper surface of the first workbench (1) is fixedly connected with a third connecting block (6); the second workbench (2) is fixedly connected with the third workbench (3); the second workbench (2) is fixedly connected with the first connecting block (4); the third workbench (3) is fixedly connected with a fourth connecting block (7); the third workbench (3) is fixedly connected with the second connecting block (5); the method is characterized in that: the device also comprises a transportation assembly, a coating assembly and a cleaning assembly; the second workbench (2) is fixedly connected with the coating component; the second workbench (2) is fixedly connected with the cleaning assembly; the third workbench (3) is fixedly connected with the cleaning assembly; the first connecting block (4) is fixedly connected with the coating component; the second connecting block (5) is fixedly connected with the cleaning assembly; the third connecting block (6) and the fourth connecting block (7) are fixedly connected with the transportation assembly; the transport assembly is in contact with the first electrode plate (8); the coating component is fixedly connected with the cleaning component.

2. The electrode plate coating line group for recycling the isolated iron and steel slag as claimed in claim 1, wherein: the transportation assembly comprises a first guide rail block (201), a first driving piece (202), a first storage box (203) and a first limiting block (204); the third connecting block (6) and the fourth connecting block (7) are fixedly connected with the first guide rail block (201); the first guide rail block (201) is connected with the first driving piece (202) in a sliding way; the first driving piece (202) is fixedly connected with the first storage box (203); the first storage box (203) is fixedly connected with the two groups of first limiting blocks (204); the inside of the first storage box (203) is in contact with the first electrode plate (8).

3. The electrode plate coating line group for recycling the isolated iron and steel slag as claimed in claim 2, wherein: the first guide rail block (201) and the first driving piece (202) are symmetrically provided with two groups by the central line of the third connecting block (6).

4. The electrode plate coating line group for recycling the isolated iron and steel slag as claimed in claim 3, wherein: the coating component comprises a first support frame (301), a first sleeve rod (302), a first transmission wheel (303), a first spline shaft (304), a first linkage block (305), a second driving piece (306), a first bevel gear (307), a second guide rail block (308), a first screw rod (309), a first sliding block (3010), a second bevel gear (3011), a first blanking device (3012), a first limiting rod (3013), a first spring (3014), a second limiting block (3015), a second linkage block (3016), a second storage box (3017), a third linkage block (3018), a first sponge block (3019), a first cavity block (3020) and a first partition plate (3021); the upper surfaces of the second workbench (2) and the first connecting block (4) are fixedly connected with a first support frame (301); two groups of first limiting rods (3013) are fixedly connected to the upper surface of the second workbench (2); two groups of first springs (3014) are fixedly connected to the upper surface of the second workbench (2); the first support frame (301) is rotationally connected with the first loop bar (302); the first support frame (301) is fixedly connected with the second driving piece (306); the first support frame (301) is fixedly connected with the second guide rail block (308); the outer surface of the first loop bar (302) is fixedly connected with a first driving wheel (303); the inside of the first loop bar (302) is in sliding connection with a first spline shaft (304); the first driving wheel (303) is in transmission connection with the cleaning assembly through a belt; the first spline shaft (304) is rotationally connected with the first linkage block (305); the first spline shaft (304) is fixedly connected with the first bevel gear (307); the first linkage block (305) is fixedly connected with the second driving piece (306); the second guide rail block (308) is rotationally connected with the first screw rod (309); the second guide rail block (308) is in sliding connection with the first sliding block (3010); the first screw rod (309) is connected with the first sliding block (3010) in a screwing mode; the first screw rod (309) is fixedly connected with the second bevel gear (3011); the first sliding block (3010) is fixedly connected with the first blanking device (3012); the two groups of first limiting rods (3013) are respectively in sliding connection with the two groups of second limiting rods (3015); the two groups of first springs (3014) are fixedly connected with the two groups of second limiting blocks (3015) respectively; two groups of second limiting blocks (3015) are fixedly connected with two groups of second linkage blocks (3016) respectively; the two groups of second linkage blocks (3016) are fixedly connected with a second storage box (3017); the two groups of second linkage blocks (3016) are fixedly connected with the first sponge block (3019); the second storage box (3017) is fixedly connected with a plurality of groups of third linkage blocks (3018); the second storage box (3017) is fixedly connected with a plurality of groups of first cavity blocks (3020); the multiple groups of third linkage blocks (3018) are fixedly connected with the first sponge block (3019); the first sponge block (3019) is contacted with a plurality of groups of first cavity blocks (3020); the insides of the groups of first cavity blocks (3020) are fixedly connected with the groups of first partition plates (3021) respectively.

5. The electrode plate coating line group for recycling the isolated iron and steel slag as claimed in claim 4, wherein: the lower surface of the first sponge block (3019) is wavy.

6. The electrode plate coating line group for recycling the isolated iron and steel slag as claimed in claim 5, wherein: the first cavity block (3020) is provided with a plurality of groups of through holes.

7. The electrode plate coating line group for recycling the isolated iron and steel slag as claimed in claim 6, wherein: the first partition plate (3021) divides the first cavity block (3020) into two cavities.

8. The electrode plate coating line group for recycling the isolated iron and steel slag as claimed in claim 7, wherein: the cleaning assembly comprises a second support frame (401), a third support frame (402), a third driving piece (403), a second sponge block (404), a second loop bar (405), a second driving wheel (406), a second spline shaft (407), a fourth linkage block (408), a fourth driving piece (409), a third bevel gear (4010), a third guide rail block (4011), a second screw rod (4012), a second sliding block (4013), a fourth bevel gear (4014), a fifth linkage block (4015), a first cleaning block (4016), a sixth linkage block (4017), a second limiting rod (4018), a second spring (4019), a first scraping frame (4020), a seventh linkage block (4021), a fifth driving piece (4022), a third sponge block (4023), an eighth linkage block (4024) and a sixth driving piece (4025); the upper surfaces of the second workbench (2) and the third workbench (3) are fixedly connected with a second support frame (401); the upper surface of the second connecting block (5) is fixedly connected with a third supporting frame (402); the second support frame (401) is fixedly connected with a third driving piece (403); the second support frame (401) is rotatably connected with the second loop bar (405); the second support frame (401) is fixedly connected with a fourth driving piece (409); the third driving piece (403) is fixedly connected with the second loop bar (405); the inside of the second loop bar (405) is in sliding connection with a second spline shaft (407); the second transmission wheel (406) is in transmission connection with the first transmission wheel (303) through a belt; the second spline shaft (407) is rotatably connected with the fourth linkage block (408); the second spline shaft (407) is fixedly connected with a third bevel gear (4010); the fourth linkage block (408) is fixedly connected with a fourth driving piece (409); the third support frame (402) is fixedly connected with a third guide rail block (4011); the third guide rail block (4011) is rotatably connected with a second screw rod (4012); the third guide rail block (4011) is connected with the second slide block (4013) in a sliding manner; the second screw rod (4012) is rotatably connected with the second slide block (4013); the second screw rod (4012) is fixedly connected with a fourth bevel gear (4014); the second sliding block (4013) is fixedly connected with a fifth linkage block (4015); the fifth linkage block (4015) is fixedly connected with the first cleaning block (4016); the first cleaning block (4016) is fixedly connected with the sixth linkage block (4017); the sixth linkage block (4017) is in sliding connection with the second limiting rod (4018); the sixth linkage block (4017) is fixedly connected with the second spring (4019); the second limiting rod (4018) is fixedly connected with the first scraping frame (4020); the second spring (4019) is fixedly connected with the first scraping frame (4020); the first scraping frame (4020) is fixedly connected with the two groups of seventh linkage blocks (4021); the first scraping frame (4020) is in contact with the two groups of third sponge blocks (4023); the first scraping frame (4020) is fixedly connected with the eighth linkage blocks (4024); the first scraping frame (4020) is in contact with the two groups of second sponge blocks (404); the two groups of seventh linkage blocks (4021) are fixedly connected with the two groups of fifth driving pieces (4022) respectively; the two groups of fifth driving pieces (4022) are fixedly connected with the two groups of third sponge blocks (4023) respectively; the two groups of eighth linkage blocks (4024) are fixedly connected with the two groups of sixth driving pieces (4025) respectively; the two groups of sixth driving pieces (4025) are fixedly connected with the two groups of second sponge blocks (404) respectively.

9. The electrode plate coating line group for recycling the isolated iron and steel slag as claimed in claim 8, wherein: the sixth linkage block (4017), the second limiting rod (4018) and the second spring (4019) are provided with four groups.

Technical Field

The invention relates to the field of steel slag, in particular to a coating line group on an electrode plate for recycling isolated steel slag.

Background

The steel is a general term for iron-carbon alloy with the carbon content of 0.02-2.11% by mass, the chemical components of the steel can be changed greatly, the steel is commonly used for producing and processing various parts and equipment, a large amount of steel slag can be generated in the process, and the steel slag has a high recycling value;

in the prior art, the steel slag is recycled by adopting an electrolysis mode, a layer of catalyst is coated on the upper surface of a negative plate by using square sponge, and then an electrolysis process is carried out, and iron element is attached to a wavy negative plate in the electrolysis process, so that high-purity iron is extracted;

and the negative plate upper surface is wavy, can warp when the sponge piece is crowded into the negative plate recess, leads to the coating in the sponge to be extruded and flow to the negative plate recess in, and then leads to the coating content in the negative plate recess too high, and the coating at sponge piece edge runs off in a large number simultaneously, and after subsequent scribbling the coating to other positions of negative plate, the phenomenon that coating content is low excessively can appear in negative plate local position.

In summary, there is a need to develop a coating line set on an electrode plate for recycling isolated iron and steel slag to overcome the above problems.

Disclosure of Invention

In order to overcome the defects that when the existing device coats a catalyst coating on a wavy cathode plate, the upper surface of the cathode plate is wavy, a sponge block deforms when being extruded into a groove of the cathode plate, so that the coating in the sponge is extruded and flows into the groove of the cathode plate, the coating content in the groove of the cathode plate is overhigh, the coating on the edge of the sponge block is greatly lost, and the coating content in the local position of the cathode plate is overhigh after coating is coated on other positions of the cathode plate subsequently, the technical problem of the invention is as follows: provides a coating line group on an electrode plate for recycling isolated iron and steel slag.

A coating line group on an electrode plate for recycling isolated iron and steel slag comprises a first workbench, a second workbench, a third workbench, a first connecting block, a second connecting block, a third connecting block, a fourth connecting block, a first electrode plate, a transportation assembly, a coating assembly and a cleaning assembly; the first workbench is fixedly connected with the second workbench; the upper surface of the first workbench is fixedly connected with a third connecting block; the second workbench is fixedly connected with the third workbench; the second workbench is fixedly connected with the first connecting block; the second workbench is fixedly connected with the coating component; the second workbench is fixedly connected with the cleaning assembly; the third workbench is fixedly connected with the fourth connecting block; the third workbench is fixedly connected with the second connecting block; the third workbench is fixedly connected with the cleaning assembly; the first connecting block is fixedly connected with the coating component; the second connecting block is fixedly connected with the cleaning assembly; the third connecting block and the fourth connecting block are fixedly connected with the transportation assembly; the transport assembly is in contact with the first electrode plate; the coating component is fixedly connected with the cleaning component.

In addition, it is particularly preferable that the transportation assembly comprises a first guide rail block, a first driving element, a first storage box and a first limiting block; the third connecting block and the fourth connecting block are fixedly connected with the first guide rail block; the first guide rail block is connected with the first driving piece in a sliding manner; the first driving piece is fixedly connected with the first storage box; the first storage box is fixedly connected with the two groups of first limiting blocks; the first containing box is internally contacted with the first electrode plate.

In addition, it is particularly preferred that the first guide rail block and the first drive element are arranged in two groups symmetrically with respect to the center line of the third connecting block.

In addition, it is particularly preferable that the coating component includes a first support frame, a first sleeve rod, a first transmission wheel, a first spline shaft, a first linkage block, a second driving piece, a first bevel gear, a second guide rail block, a first lead screw, a first slider, a second bevel gear, a first discharger, a first limit rod, a first spring, a second limit block, a second linkage block, a second storage box, a third linkage block, a first sponge block, a first cavity block and a first partition plate; the upper surfaces of the second workbench and the first connecting block are fixedly connected with a first supporting frame; two groups of first limiting rods are fixedly connected to the upper surface of the second workbench; two groups of first springs are fixedly connected to the upper surface of the second workbench; the first support frame is rotationally connected with the first sleeve rod; the first support frame is fixedly connected with the second driving piece; the first support frame is fixedly connected with the second guide rail block; the outer surface of the first sleeve rod is fixedly connected with the first driving wheel; the inside of the first sleeve rod is in sliding connection with the first spline shaft; the first driving wheel is in transmission connection with the cleaning assembly through a belt; the first spline shaft is rotationally connected with the first linkage block; the first spline shaft is fixedly connected with the first bevel gear; the first linkage block is fixedly connected with the second driving piece; the second guide rail block is rotationally connected with the first screw rod; the second guide rail block is connected with the first slide block in a sliding manner; the first screw rod is in screwed connection with the first sliding block; the first screw rod is fixedly connected with the second bevel gear; the first sliding block is fixedly connected with the first discharger; the two groups of first limiting rods are respectively connected with the two groups of second limiting blocks in a sliding manner; the two groups of first springs are fixedly connected with the two groups of second limiting blocks respectively; the two groups of second limiting blocks are fixedly connected with the two groups of second linkage blocks respectively; the two groups of second linkage blocks are fixedly connected with the second storage box; the two groups of second linkage blocks are fixedly connected with the first sponge block; the second storage box is fixedly connected with a plurality of groups of third linkage blocks; the second storage box is fixedly connected with the plurality of groups of first cavity blocks; the multiple groups of third linkage blocks are fixedly connected with the first sponge block; the first sponge block is contacted with the plurality of groups of first cavity blocks; the insides of the multiple groups of first cavity blocks are fixedly connected with the multiple groups of first partition plates respectively.

Further, it is particularly preferable that the lower surface of the first sponge block is waved.

In addition, it is particularly preferred that a plurality of sets of through holes are provided on the first cavity block.

In addition, it is particularly preferred that the first partition divides the first cavity block into two cavities.

In addition, it is particularly preferable that the cleaning assembly includes a second support frame, a third driving member, a second sponge block, a second loop bar, a second driving wheel, a second spline shaft, a fourth linkage block, a fourth driving member, a third bevel gear, a third guide rail block, a second screw rod, a second slider, a fourth bevel gear, a fifth linkage block, a first cleaning block, a sixth linkage block, a second limiting rod, a second spring, a first scraping frame, a seventh linkage block, a fifth driving member, a third sponge block, an eighth linkage block and a sixth driving member; the upper surfaces of the second workbench and the third workbench are fixedly connected with the second support frame; the upper surface of the second connecting block is fixedly connected with the third supporting frame; the second support frame is fixedly connected with the third driving piece; the second support frame is rotatably connected with the second sleeve rod; the second support frame is fixedly connected with the fourth driving piece; the third driving piece is fixedly connected with the second sleeve rod; the inner part of the second sleeve rod is in sliding connection with the second spline shaft; the second transmission wheel is in transmission connection with the first transmission wheel through a belt; the second spline shaft is rotationally connected with the fourth linkage block; the second spline shaft is fixedly connected with the third bevel gear; the fourth linkage block is fixedly connected with the fourth driving piece; the third support frame is fixedly connected with the third guide rail block; the third guide rail block is rotationally connected with the second screw rod; the third guide rail block is connected with the second slide block in a sliding manner; the second screw rod is in screwed connection with the second sliding block; the second screw rod is fixedly connected with a fourth bevel gear; the second sliding block is fixedly connected with the fifth linkage block; the fifth linkage block is fixedly connected with the first cleaning block; the first cleaning block is fixedly connected with the sixth linkage block; the sixth linkage block is in sliding connection with the second limiting rod; the sixth linkage block is fixedly connected with the second spring; the second limiting rod is fixedly connected with the first scraping frame; the second spring is fixedly connected with the first scraping frame; the first scraping frame is fixedly connected with the two groups of seventh linkage blocks; the first scraping frame is in contact with the two groups of third sponge blocks; the first scraping frame is fixedly connected with the two groups of eighth linkage blocks; the first scraping frame is in contact with the two groups of second sponge blocks; the two groups of seventh linkage blocks are fixedly connected with the two groups of fifth driving pieces respectively; the two groups of fifth driving pieces are fixedly connected with the two groups of third sponge blocks respectively; the two groups of eighth linkage blocks are fixedly connected with the two groups of sixth driving pieces respectively; and the two groups of sixth driving pieces are fixedly connected with the two groups of second sponge blocks respectively.

Further, it is particularly preferable that four sets of the sixth link block, the second stopper rod, and the second spring are provided.

Compared with the prior art, the invention has the following advantages:

the device comprises a negative plate, a sponge block, a negative plate groove, a negative plate edge, a negative plate bottom and a negative plate bottom, wherein the sponge block is extruded into the negative plate groove, and the sponge block is extruded into the negative plate groove;

designing a transportation assembly, a coating assembly and a cleaning assembly; when the device is prepared for working, the device is placed on a horizontal plane, a power supply is switched on, the operation controller control device starts to operate, the transportation assemblies on the third connecting block and the fourth connecting block drive the first electrode plate to move towards the direction of the coating assembly, the coating assembly is triggered to operate in the operation process of the transportation assemblies, the sponge block in the coating assembly is upwards lifted for a certain distance, when the head of the first electrode plate moves to the lower part of the sponge block, the transportation assemblies stop acting on the coating assembly, the sponge block moves downwards to return to the original position to be in contact with the upper surface of the first electrode plate, the phenomenon that the first electrode plate collides with the sponge block due to incomplete alignment is avoided, further the phenomena that the sponge block is deformed and a large amount of coatings in the sponge block are stained on the side surface of the first electrode plate are avoided, then the first electrode plate continues to move, and the coating assembly on the second workbench is enabled to paint the upper surface of the first electrode plate, in the process, the coating on the sponge block is injected into the coating assembly on the first connecting block in a segmented manner, so that the coating can quickly permeate to each part of the sponge block, meanwhile, the coating assembly can be used for segmenting and blocking the sponge block according to the height of the sponge block, the coating at the middle-high position of the sponge block is prevented from gathering to the lower position, the phenomena that the coating in the groove on the upper surface of the first electrode plate is too much and the coating at the protruding part is too little are avoided, then the first electrode plate is moved to the lower part of the cleaning assembly, then the cleaning assembly can scrape the coating remained on the side surface of the first electrode plate downwards, so that the residual coating gathers at the lower part of the first electrode plate and then the coating is sucked and removed by using the sponge block, the phenomenon that the sponge block is extruded to the upper surface of the first electrode plate when the sponge block is directly used for cleaning the first electrode plate is avoided, and further the phenomenon that the coating on the upper surface of the first electrode plate is removed when the residual coating is treated is avoided, then, the first electrode plate is taken out manually, part of the coating flows into the conveying assembly along the side face of the first electrode plate, and the cleaning assembly on the third workbench and the second connecting block removes the coating completely, so that the phenomenon that the next first electrode plate cannot be placed into the conveying assembly after the coating becomes hard is avoided;

when the device is used, the automatic coating of the electrode plate by using the wave sponge block is realized, the phenomenon of uneven coating caused by extrusion during coating of common sponge is avoided, meanwhile, the coating is injected after the wave sponge block is automatically separated, the phenomenon that the coating at the middle-high position of the sponge block is gathered to the lower position is avoided, the coating remained on the side surface of the electrode plate is automatically cleaned, and the phenomenon that the coating on the upper surface of the electrode plate is lost is avoided.

Drawings

Fig. 1 is a schematic perspective view of a first embodiment of the present disclosure;

FIG. 2 is a schematic perspective view of a second embodiment of the present application;

FIG. 3 is a perspective view of a transport assembly of the present application;

FIG. 4 is a top view of a portion of the structure of the transport assembly of the present application;

FIG. 5 is a perspective view of a coating assembly of the present application;

FIG. 6 is a schematic view of a first partially assembled body structure of a coating assembly of the present application;

FIG. 7 is a schematic view of a second partially assembled body structure of a coating assembly of the present application;

FIG. 8 is a perspective view of a third portion of a coating assembly according to the present application;

FIG. 9 is an enlarged view of the present application at A;

FIG. 10 is an enlarged view of the present application B;

FIG. 11 is a perspective view of a cleaning assembly of the present application;

FIG. 12 is a perspective view of a portion of the cleaning assembly of the present application;

FIG. 13 is a side view of a portion of the structure of the cleaning assembly of the present application;

fig. 14 is an enlarged view of the present application C.

In the figure: 1. a first workbench, 2, a second workbench, 3, a third workbench, 4, a first connecting block, 5, a second connecting block, 6, a third connecting block, 7, a fourth connecting block, 8, a first electrode plate, 201, a first guide rail block, 202, a first driving member, 203, a first storage box, 204, a first limiting block, 301, a first support frame, 302, a first loop bar, 303, a first driving wheel, 304, a first spline shaft, 305, a first linkage block, 306, a second driving member, 307, a first bevel gear, 308, a second guide rail block, 309, a first lead screw, 3010, a first slider, 3011, a second bevel gear, 3012, a first feeder, 3013, a first limiting rod, 3014, a first spring, 3015, a second limiting block, 3016, a second linkage block, 3017, a second storage box, 3018, a third linkage block, 3019, a first sponge block, 3020, a first hollow block, 3021, a first partition board, 3021, 401. the cleaning device comprises a second support frame, 402, a third support frame, 403, a third driving piece, 404, a second sponge block, 405, a second loop bar, 406, a second driving wheel, 407, a second spline shaft, 408, a fourth linkage block, 409, a fourth driving piece, 4010, a third bevel gear, 4011, a third guide rail block, 4012, a second lead screw, 4013, a second sliding block, 4014, a fourth bevel gear, 4015, a fifth linkage block, 4016, a first cleaning block, 4017, a sixth linkage block, 4018, a second limiting rod, 4019, a second spring, 4020, a first scraping frame, 4021, a seventh linkage block, 4022, a fifth driving piece, 4023, a third sponge block, 4024, an eighth linkage block, 4025 and a sixth driving piece.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings in conjunction with the following detailed description. It should be understood that the description is intended to be exemplary only, and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

Examples

A coating line group on an electrode plate for recycling isolated iron and steel slag comprises a first workbench 1, a second workbench 2, a third workbench 3, a first connecting block 4, a second connecting block 5, a third connecting block 6, a fourth connecting block 7, a first electrode plate 8, a transportation assembly, a coating assembly and a cleaning assembly, wherein the first workbench 1 and the second workbench 2 are connected with the first connecting block 4; the first workbench 1 is fixedly connected with the second workbench 2; the upper surface of the first workbench 1 is fixedly connected with a third connecting block 6; the second workbench 2 is fixedly connected with the third workbench 3; the second workbench 2 is fixedly connected with the first connecting block 4; the second workbench 2 is fixedly connected with a coating component with the function of coating; the second workbench 2 is fixedly connected with a cleaning component with the function of cleaning residual paint; the third workbench 3 is fixedly connected with a fourth connecting block 7; the third workbench 3 is fixedly connected with a second connecting block 5; the third workbench 3 is fixedly connected with the cleaning assembly; the first connecting block 4 is fixedly connected with the coating component; the second connecting block 5 is fixedly connected with the cleaning assembly; the third connecting block 6 and the fourth connecting block 7 are fixedly connected with a conveying assembly with the function of conveying the first electrode plate 8; the transport assembly is in contact with the first electrode plate 8; the coating component is fixedly connected with the cleaning component.

When the device is prepared for working, the device is placed on a horizontal plane, a power supply is switched on, the operation controller control device starts to operate, the transportation assemblies on the third connecting block 6 and the fourth connecting block 7 drive the first electrode plate 8 to move towards the direction of the coating assembly, the coating assembly is triggered to operate in the operation process of the transportation assembly, the sponge block in the coating assembly is upwards lifted for a certain distance, when the head of the first electrode plate 8 moves to the lower part of the sponge block, the transportation assembly stops acting on the coating assembly, the sponge block moves downwards to return to the original position to be in contact with the upper surface of the first electrode plate 8, the phenomenon that the first electrode plate 8 impacts the sponge block due to incomplete alignment is avoided, further the phenomena that the sponge block is deformed and a large amount of coating in the sponge block is stained on the side surface of the first electrode plate 8 are avoided, then the first electrode plate 8 continues to move, and the coating assembly on the second workbench 2 connected with the first workbench 1 paints on the upper surface of the first electrode plate 8, in the process, the coating on the coating component on the first connecting block 4 is injected into the sponge block in a segmented manner, so that the coating can rapidly permeate to each part of the sponge block, meanwhile, the coating component can perform segmented separation on the sponge block according to the height of the sponge block, the coating at the middle-high position of the sponge block is prevented from gathering to the lower position, the phenomena that the coating in the groove of the upper surface of the first electrode plate 8 is too much and the coating at the protruding part is too little are avoided, then the first electrode plate 8 continues to move to the lower part of the cleaning component, then the cleaning component can scrape the coating remained on the side surface of the first electrode plate 8 downwards, so that the residual coating gathers at the lower part of the first electrode plate 8 and then uses the sponge block to suck the coating, the phenomenon that the sponge block extrudes to the upper surface of the first electrode plate 8 when the side surface of the first electrode plate 8 is directly cleaned by using the sponge block is avoided, and the phenomenon that the coating on the upper surface of the first electrode plate 8 is removed when the residual coating is treated is further avoided, and then the first electrode plate 8 is manually taken out, part of the coating flows into the conveying assembly along the side surface of the first electrode plate 8, the cleaning assemblies on the third workbench 3 and the second connecting block 5 remove the coating completely, and the phenomenon that the next first electrode plate 8 cannot be placed into the conveying assembly after the coating becomes hard is avoided.

As shown in fig. 3-4, the transportation assembly includes a first guide rail block 201, a first driving member 202, a first storage box 203, and a first limiting block 204; the third connecting block 6 and the fourth connecting block 7 are fixedly connected with the first guide rail block 201; the first guide rail block 201 is connected with the first driving piece 202 in a sliding manner; the first driving part 202 is fixedly connected with the first storage box 203; the first storage box 203 is fixedly connected with the two groups of first limiting blocks 204; the first storage case 203 is internally in contact with the first electrode plate 8.

First, first guide rail piece 201 drives first driving piece 202 transmission first receiver 203 to the motion of clearance subassembly direction, and first receiver 203 drives first electrode board 8 motion, and first receiver 203 drives two sets of first stopper 204 motions simultaneously, makes two sets of first stopper 204 touch the coating subassembly function, has realized the automatic motion of first electrode board 8 that drives during the use, has still realized touching the coating subassembly function.

The first guide rail block 201 and the first driving member 202 are symmetrically arranged in two groups by the central line of the third connecting block 6.

The first storage box 203 can be driven to move at the same time, and stability is improved.

As shown in fig. 5 to 10, the coating assembly includes a first support frame 301, a first sleeve 302, a first driving wheel 303, a first spline shaft 304, a first linkage block 305, a second driving piece 306, a first bevel gear 307, a second guide block 308, a first lead screw 309, a first slider 3010, a second bevel gear 3011, a first stripper 3012, a first limit rod 3013, a first spring 3014, a second limit block 3015, a second linkage block 3016, a second storage box 3017, a third linkage block 3018, a first sponge block 3019, a first cavity block 3020, and a first partition 3021; the upper surfaces of the second workbench 2 and the first connecting block 4 are fixedly connected with a first support frame 301; two groups of first limiting rods 3013 are fixedly connected to the upper surface of the second workbench 2; two groups of first springs 3014 are fixedly connected to the upper surface of the second workbench 2; the first support frame 301 is rotatably connected with the first sleeve 302; the first support frame 301 is fixedly connected with the second driving piece 306; the first support frame 301 is fixedly connected with the second guide rail block 308; the outer surface of the first loop bar 302 is fixedly connected with a first driving wheel 303; the inside of the first sleeve 302 is slidably connected with a first spline shaft 304; the first driving wheel 303 is in transmission connection with the cleaning assembly through a belt; the first spline shaft 304 is rotationally connected with the first linkage block 305; the first spline shaft 304 is fixedly connected with a first bevel gear 307; the first linkage block 305 is fixedly connected with the second driving member 306; the second guide rail block 308 is rotatably connected with the first lead screw 309; the second guide block 308 is connected with the first slider 3010 in a sliding manner; the first screw rod 309 is screwed with the first slide block 3010; the first screw rod 309 is fixedly connected with the second bevel gear 3011; the first slider 3010 is fixedly connected with the first blanking device 3012; the two groups of first limiting rods 3013 are slidably connected to the two groups of second limiting blocks 3015 respectively; the two groups of first springs 3014 are fixedly connected to the two groups of second limiting blocks 3015 respectively; the two groups of second limiting blocks 3015 are fixedly connected to the two groups of second linkage blocks 3016 respectively; the two groups of second linkage blocks 3016 are fixedly connected with a second storage box 3017; the two groups of second linkage blocks 3016 are fixedly connected with the first sponge block 3019; the second storage box 3017 is fixedly connected with a plurality of groups of third linkage blocks 3018; the second storage box 3017 is fixedly connected with a plurality of groups of first cavity blocks 3020; the multiple groups of third link blocks 3018 are all fixedly connected with the first sponge block 3019; the first sponge block 3019 is in contact with a plurality of groups of first cavity blocks 3020; the insides of the plurality of groups of first cavity blocks 3020 are fixedly connected with the plurality of groups of first partition boards 3021 respectively.

When the first storage box 203 drives two sets of first limiting blocks 204 to respectively contact with two sets of second limiting blocks 3015, the two sets of first limiting blocks 204 respectively extrude the two sets of second limiting blocks 3015, the two sets of second limiting blocks 3015 respectively slide upwards under the limiting action of the two sets of first limiting rods 3013, the two sets of second limiting blocks 3015 respectively drive the two sets of second linkage blocks 3016 to move upwards, the two sets of second linkage blocks 3016 simultaneously drive the second storage box 3017 to move upwards, the second storage box 3017 drives the multiple sets of third linkage blocks 3018 to move upwards, the multiple sets of third linkage blocks 3018 simultaneously drive the first sponge block 3019 to move upwards for a certain distance, simultaneously the two sets of first springs 3014 are stretched, when the two sets of first limiting blocks 204 continuously move away from the two sets of second limiting blocks 3015, at the head of the first electrode plate 8 is just below the first sponge block 3019, then the two sets of first springs 3014 drive the second limiting blocks 3015 to move downwards to return to the original position, the first sponge block 3019 is moved downwards to contact the upper surface of the first electrode plate 8, so that the phenomenon that the first electrode plate 8 collides the first sponge block 3019 due to incomplete alignment is avoided, then the cleaning assembly drives the first driving wheel 303 to drive the first sleeve 302 to rotate, the first sleeve 302 drives the first spline shaft 304 to drive the first bevel gear 307 to rotate, then the second driving piece 306 on the first support frame 301 pushes the first linkage block 305 to move, so that the first linkage block 305 drives the first spline shaft 304 to drive the first bevel gear 307 to engage with the second bevel gear 3011, then the first bevel gear 307 drives the second bevel gear 3011 to drive the first lead screw 309 to rotate, the first lead screw 309 drives the first slider 3010 to slide on the second guide rail block 308, the cleaning assembly drives the first driving wheel 303 to rotate positively and negatively, so that the first slider 3010 makes reciprocating motion, and then the first slider 3010 drives the first discharger 3012 to make reciprocating motion, then the first material dropping device 3012 starts to pour the coating downwards, the coating flows into the second storage box 3017, then flows into the first sponge block 3019 from the through hole of the second storage box 3017, meanwhile, part of the coating flows into the multiple groups of first cavity blocks 3020, then flows into the deep part of the first sponge block 3019 from the through hole of the first cavity blocks 3020, so as to improve the efficiency, at this time, the multiple groups of first cavity blocks 3020 divide the first sponge block 3019 into multiple sections, the multiple groups of first partition boards 3021 can prevent the coating of the groove part in the first sponge block 3019 from flowing to the convex part, so that the coating is uniformly distributed in the first sponge block 3019, then the first electrode plate 8 continues to move, so that the first sponge block 3019 can uniformly coat the coating on the upper surface of the first electrode plate 8, thereby realizing that the coating is automatically coated on the electrode plate by the wave sponge block, avoiding the phenomenon of uneven coating caused by extrusion during the coating of the common sponge, meanwhile, the coating is injected after the wave sponge is automatically separated, so that the phenomenon that the coating at the high position in the sponge block is gathered to the low position is avoided.

The lower surface of the first sponge block 3019 is wavy.

Can just be laminated with 8 upper surfaces of first electrode board, avoid ordinary sponge to be extruded when paining and the inhomogeneous phenomenon of paining that leads to.

A plurality of groups of through holes are arranged on the first cavity block 3020.

The coating can rapidly flow into the first sponge block 3019 from the through hole, and the efficiency is improved.

The first partition 3021 divides the first cavity block 3020 into two cavities.

The coating can be blocked to prevent the coating in the concave portion of the first sponge block 3019 from flowing to the convex portion.

As shown in fig. 11 to 14, the cleaning assembly includes a second support frame 401, a third support frame 402, a third driving member 403, a second sponge block 404, a second loop bar 405, a second driving wheel 406, a second spline shaft 407, a fourth link block 408, a fourth driving member 409, a third bevel gear 4010, a third guide block 4011, a second screw 4012, a second slider 4013, a fourth bevel gear 4014, a fifth link block 4015, a first cleaning block 4016, a sixth link block 4017, a second limit rod 4018, a second spring 4019, a first scraping frame 4020, a seventh link block 4021, a fifth driving member 4022, a third sponge block 4023, an eighth link block 4024, and a sixth driving member 4025; the upper surfaces of the second workbench 2 and the third workbench 3 are fixedly connected with a second support frame 401; the upper surface of the second connecting block 5 is fixedly connected with the third supporting frame 402; the second support frame 401 is fixedly connected with the third driving piece 403; the second support frame 401 is rotatably connected with the second sleeve rod 405; the second support frame 401 is fixedly connected with the fourth driving part 409; the third driving member 403 is fixedly connected with the second sleeve rod 405; the inside of the second sleeve rod 405 is connected with a second spline shaft 407 in a sliding manner; the second transmission wheel 406 is in transmission connection with the first transmission wheel 303 through a belt; the second spline shaft 407 is rotatably connected with the fourth linkage block 408; the second spline shaft 407 is fixedly connected with a third bevel gear 4010; the fourth linkage block 408 is fixedly connected with a fourth driving part 409; the third support frame 402 is fixedly connected with a third guide rail block 4011; the third guide rail block 4011 is rotatably connected with a second screw 4012; the third guide rail block 4011 is connected with the second slide block 4013 in a sliding manner; the second screw 4012 is screwed with the second slide block 4013; the second screw 4012 is fixedly connected with a fourth bevel gear 4014; the second slide block 4013 is fixedly connected with a fifth linkage block 4015; the fifth linkage block 4015 is fixedly connected with the first cleaning block 4016; the first cleaning block 4016 is fixedly connected with a sixth linkage block 4017; the sixth linkage block 4017 is connected with the second limit rod 4018 in a sliding manner; the sixth linkage block 4017 is fixedly connected with a second spring 4019; the second limiting rod 4018 is fixedly connected with the first scraping frame 4020; the second spring 4019 is fixedly connected with the first scraping frame 4020; the first scraping frame 4020 is fixedly connected with the two groups of seventh linkage blocks 4021; the first scraping frame 4020 is in contact with the two groups of third sponge blocks 4023; the first scraping frame 4020 is fixedly connected with the two groups of eighth linkage blocks 4024; the first scraping frame 4020 is in contact with the two groups of second sponge blocks 404; the two groups of seventh linkage blocks 4021 are fixedly connected with the two groups of fifth driving pieces 4022 respectively; the two groups of fifth driving pieces 4022 are fixedly connected with the two groups of third sponge blocks 4023 respectively; the two groups of eighth linkage blocks 4024 are fixedly connected with the two groups of sixth driving pieces 4025 respectively; the two sets of sixth driving members 4025 are fixedly connected to the two sets of second sponge blocks 404, respectively.

Firstly, the third driving member 403 on the second support frame 401 drives the second sleeve rod 405 to drive the second spline shaft 407 to rotate, the second sleeve rod 405 drives the second driving wheel 406 to drive the coating component to operate, after the coating is coated, part of the coating remains on four sides of the first electrode plate 8, when the transport component drives the first electrode plate 8 to move under the first cleaning block 4016, the fourth driving member 409 drives the fourth linkage block 408 to drive the second spline shaft 407 to move, so that the second spline shaft 407 drives the third bevel gear 4010 to engage with the fourth bevel gear 4014, then the second sleeve rod 405 drives the second spline shaft 407 to drive the third bevel gear 4010 to rotate, the third bevel gear 4010 drives the fourth bevel gear 4014 to drive the second lead screw 4012 to rotate, the second lead screw 4012 drives the second slide block 4013 to move, so that the second slide block 4013 slides downwards on the third guide rail block 4011 connected with the third support frame 402, and the second slide block 4015 moves downwards, the fifth linkage block 4015 drives the components associated with the fifth linkage block to move, so that the first scraping frame 4020 moves downwards, the first scraping frame 4020 can just sleeve the first electrode plate 8 when moving downwards, namely four sides inside the first scraping frame 4020 are respectively contacted with four side surfaces of the first electrode plate 8, then the first scraping frame 4020 pushes the coating above the four side surfaces of the first electrode plate 8 to the lower part, then the two groups of fifth driving pieces 4022 on the two groups of seventh linkage blocks 4021 drive the two groups of third sponge blocks 4023 to move, so that the two groups of third sponge blocks 4023 are attached to the lower parts of the two side surfaces of the first electrode plate 8, so that the residual coating is sucked, the two groups of third sponge blocks 4023 move back to the original position, then the two groups of sixth driving pieces 4025 on the two groups of eighth linkage blocks 4024 drive the two groups of second sponge blocks 404 to move, so that the two groups of second sponge blocks 404 are attached to the other two side surfaces of the first electrode plate 8, so as to suck and remove the residual coating, the two sets of second sponge blocks 404 move back to the original position, thereby avoiding the phenomenon that the sponge blocks are extruded to the upper surface of the first electrode plate 8 when the sponge blocks are directly used for cleaning the side surface of the first electrode plate 8, then, the first scraping frame 4020 drives the components associated therewith to move back upward, a part of the coating flows into the first storage box 203 from the side of the first electrode plate 8, then, the first electrode plate 8 is manually taken out, and then the first cleaning block 4016 is downwardly moved to be inserted into the first receiving box 203, the paint in the first storage box 203 is sucked and removed, in the process, the first scraping frame 4020 is blocked and limited, so that the first cleaning block 4016 drives the sixth linkage block 4017 to slide downwards on the second limiting rod 4018, meanwhile, the sixth linkage block 4017 compresses the second spring 4019, so that the paint remained on the side surface of the electrode plate is automatically cleaned completely during use, and the phenomenon of paint loss on the upper surface of the electrode plate is avoided.

The sixth linkage block 4017, the second stopper 4018, and the second spring 4019 are provided with four groups.

Can carry out spacingly to first cleaning block 4016 simultaneously, increase stability.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting the protection scope of the present invention, and although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.