CN115741122B - Cutting device and method for machining hydrogen fuel cell plate - Google Patents

Abstract

The invention belongs to the technical field of fuel cells, and particularly relates to a cutting device and a processing method for processing a hydrogen fuel cell plate, wherein the cutting device comprises the following steps: a conveying part for conveying the battery plate, a cutting part for grooving and cutting the outer wall of the battery plate and a polishing part for polishing the slotted hole of the outer wall of the battery plate; the invention can solve the problems existing in the current grooving treatment process of the surface flow channel of the battery plate: 1. the uneven inner wall of the flow channel on the surface of the battery plate causes the influence on the reaction of substances such as gas and the like in the use process of the battery plate, and the heat emission in the use process of the battery plate is easily influenced; 2. the cell plate is easy to generate relative movement in the slotting process of the cell plate flow channel, so that the formed flow channel is bent, the circulation efficiency of substances such as gas and the like in the subsequent use process is affected, and the like.

Description

Cutting device and method for machining hydrogen fuel cell plate

Technical Field

The invention belongs to the technical field of fuel cells, and particularly relates to a cutting device and a cutting method for processing a hydrogen fuel cell plate.

Background

The hydrogen fuel cell plate is one of important parts of the fuel cell, and mainly plays a role in separating fuel and oxidant and preventing gas from permeating; collecting and conducting current; the surface of the battery plate is provided with a flow channel which is designed and processed, so that gas can be uniformly distributed to the reaction layer of the electrode to carry out electrode reaction; can discharge heat and keep the temperature field of the battery uniform.

At present, most of the flow channels on the surface of the battery plate are subjected to mechanical centralized grooving, but in the grooving process of the flow channels on the surface of the battery plate, the following problems mainly exist: 1. the uneven inner wall of the flow channel on the surface of the battery plate causes the influence on the reaction of substances such as gas and the like in the use process of the battery plate, and the heat emission in the use process of the battery plate is easily influenced; 2. the cell plate is easy to generate relative movement in the process of slotting the cell plate flow channel, so that the formed flow channel is bent, and the circulation efficiency of substances such as gas and the like in the subsequent use process is influenced.

Therefore, in order to improve the opening effect of the flow channels on the surface of the cell plate, the invention provides a cutting device and a processing method for processing the hydrogen fuel cell plate.

Disclosure of Invention

In order to solve the above technical problems, the present invention provides a cutting device for processing a hydrogen fuel cell plate, comprising: a conveying part for conveying the battery plate, a cutting part for grooving and cutting the outer wall of the battery plate and a polishing part for polishing the slotted hole of the outer wall of the battery plate; the conveying part comprises a feeding conveying module, a pushing conveying module and a stacking conveying module; the upper end that is located the feeding and transports the module is provided with cutting part, and the left end that the feeding transported the module is provided with the pushing away material and transports the module, and the left side that is located the pushing away material and transports the module is provided with the portion of polishing, and the left side that is located the portion of polishing is provided with the windrow and transports the module.

The polishing part comprises a polishing frame arranged between the pushing and conveying module and the stacking and conveying module; the inner wall of the top end of the polishing frame is provided with a pushing cylinder, lifting frames are arranged on the two sides of the polishing frame in a sliding mode, and the telescopic end of the pushing cylinder is connected with the lifting frames; the lifting frame is of a frame structure, a limiting partition plate is arranged at an opening of the lifting frame, the inner wall of the frame of the lifting frame is of an inclined structure, vertical downward sliding grooves are uniformly formed in the inner wall of the frame of the lifting frame from front to back, a working motor is arranged at the upper end of the lifting frame in a sliding mode through a motor seat, a threaded rotating rod is arranged on an output shaft of the working motor, the lower end of the threaded rotating rod is arranged on the inner wall of the bottom end of the lifting frame in a sliding mode through a sliding block, and the threaded rotating rod is connected with the sliding block through a bearing; the outer wall threaded connection of screw thread bull stick has the transfer frame, and transfers the inside of frame slidable mounting at the crane, the lateral wall of transfer frame evenly be provided with the leading wheel, the leading wheel be located inside the spout, transfer the frame and be type structure, and transfer the inside of frame and evenly install the grinding head through the bolt.

Preferably; the feeding and conveying module comprises a supporting frame, and a conveying belt is arranged in the supporting frame; a supporting ring is arranged on the inner wall of the supporting frame and is positioned in the conveying belt; the upper end of the support frame is symmetrically provided with a material guide plate, the right end of the material guide plate is of an outward expansion structure, and the inner walls of the flaring which are mutually close to the two material guide plates are movably provided with idler wheels.

Preferably; the pushing and conveying module comprises a tripod arranged at the left end of the supporting frame, and an inclined turning plate is arranged on the tripod; square holes are formed in the material turning plates, and material guide strips are arranged on the material turning plates positioned at two sides of the square holes; the inner wall of the lower end of the square hole is provided with a pushing plate in a hinging manner, air holes are uniformly formed in the pushing plate, an air suction pump is arranged on the pushing plate and communicated with the air holes, a pushing cylinder is arranged on the supporting frame in a hinging manner, and the top end of the pushing cylinder is hinged with the pushing plate; and a material limiting transverse plate is arranged on the material guide plate at the lower end of the square hole.

Preferably; the stacking conveying module comprises a moving frame, a conveying belt is arranged on the moving frame, and a sponge cushion is arranged on the conveying belt.

Preferably; the cutting part comprises a cutting frame positioned above the supporting frame; the upper end of the cutting frame is provided with a dust suction pump, and the upper end of the cutting frame is provided with a receiving box; the discharging pipe of the dust suction pump is positioned in the material receiving box; an adjusting cylinder is arranged in the middle of the inner wall of the upper end of the cutting frame, and spring rods are uniformly arranged on the outer side of the adjusting cylinder on the cutting frame; the movable end of the spring rod is commonly connected with an execution frame, and the telescopic end of the adjusting cylinder is connected with the execution frame; two symmetrical driving lead screws are arranged in the execution frame in parallel, and the driving lead screws are connected with the execution frame through bearings; one end of the driving screw rod penetrates through the execution frame to be located at the outer side of the execution frame, and a belt wheel is arranged at one end of the driving screw rod located at the outer side of the execution frame; the position on the same side of the actuating frame as the belt wheel is provided with an adjusting motor through a motor seat, and an output shaft of the adjusting motor is also provided with the belt wheel; the three belt wheels are positioned on the same straight line, and the three belt wheels are connected together through the toothed belt.

Preferably; the cutting part also comprises moving seats which are respectively arranged on the driving screw rod in a threaded connection mode, a transverse screw rod is arranged between the two moving seats in a co-rotation mode, an auxiliary motor is arranged on one of the moving seats, and an output shaft of the auxiliary motor is fixedly connected with one end of the transverse screw rod; a limiting rod is also arranged between the two movable seats, a cutting seat is arranged on the limiting rod in a sliding manner, the cutting seat is in threaded connection with the transverse screw rod, and a cutting head is arranged in the cutting seat in a rotating manner; the bevel gear is arranged at one end of the cutting head, which is positioned in the cutting seat, the cutting seat is also provided with a cross rod through a bearing, and the bevel gear is also arranged at one end of the cross rod, which is close to the interior of the cutting seat, and the two bevel gears are meshed with each other; one end of the cross rod, which is positioned outside the cutting seat, is also provided with a belt wheel; the top end of the cutting seat is provided with an execution motor through a motor seat, the execution motor is also provided with a belt wheel, and the belt wheel on the cross rod is also connected with the belt wheel on the execution motor through a belt; a material suction pipe is obliquely arranged in the cutting seat at a position close to the cutting head; the suction pipe of the dust suction pump is positioned in the cutting seat and connected with the suction pipe.

Preferably; the cutting part also comprises an execution telescopic rod which is uniformly arranged at the lower end of the execution rack; a limiting ring is arranged on the outer wall of the middle part of the telescopic rod of the execution telescopic rod, and positioning rods are uniformly arranged on the limiting ring in a rotating mode; the lower extreme of locating lever is provided with the rubber lug, is located the flexible end circumference outer wall of execution telescopic link and evenly articulates and be provided with the regulation telescopic link, adjusts the flexible end and the locating lever one-to-one of telescopic link, and adjusts the flexible end and be connected with the locating lever of telescopic link.

Preferably; the lower end of the execution frame is fixedly provided with a limiting frame through a spring rod, and the limiting frame is positioned below the rubber lug.

The invention also provides a processing method of the hydrogen fuel cell plate, which comprises the following steps: s1: firstly, the battery plates to be processed are sequentially placed on a feeding conveying module in sequence manually to be conveyed, and when the battery plates are conveyed to the position right below the cutting part, the battery plates are limited through the cutting part and are sequentially processed and grooved.

S2: after the surface grooving processing of the battery plate is finished; separating the cutting part from the current battery plate, continuously grooving the next conveyed battery plate, continuously conveying the grooved battery plate to the position of a pushing and conveying module, and pushing the battery plate to be in an upright state after being adsorbed and fixed by the cutting part; and then polishing the slot hole position on the polishing part through a polishing treatment.

S3: after the slotted holes of the slotted battery plates are polished, the slotted holes are separated from the current battery plates through the polishing parts, the battery plates are continuously pushed onto the stacking conveying module through the pushing conveying module, and then the battery plates are conveyed to a specified position through the stacking conveying module for collection.

Compared with the related art, the invention has the following beneficial effects: 1. the cutting part provided by the invention can be used for positioning and limiting for a plurality of times in the process of opening the flow channel on the surface of the battery plate, so that the stability of the battery plate in the slotting process is ensured, and the formed flow channel is effectively prevented from being deviated.

2. The polishing part provided by the invention can ensure that the inner wall of the flow channel on the battery plate is uniform and smooth, and prevent the rough inner wall of the flow channel of the battery plate from influencing the reaction of substances such as gas and the like; the polishing part can limit the battery plate when polishing the battery plate, so that the battery plate is prevented from shaking, and the adaptability of the battery plate to a battery plate flow channel is improved by adopting the polishing heads with adjustable rows; and the processing treatment of various battery boards is convenient.

Drawings

Fig. 1 is a schematic structural diagram of a cutting device for processing a hydrogen fuel cell plate according to an embodiment of the present invention.

Fig. 2 is a schematic perspective view of the rear position of fig. 1 according to the present invention.

Fig. 3 is a schematic view of a portion of the structure between the feed conveyor module and the cutting section of the present invention.

Fig. 4 is a cross-sectional view between the stacker transport module and the pusher transport module and the sanding section of the present invention.

Fig. 5 is a cross-sectional view between the feed conveyor module and the cutting section of the present invention.

Fig. 6 is an enlarged schematic view of the partial structure of fig. 5 a according to the present invention.

Fig. 7 is a sectional view showing the internal structure of the cutting part of the present invention.

Fig. 8 is a side view of the internal structure of the cutting part of the present invention.

Fig. 9 is a cross-sectional view showing the internal structure of the grinding part of the present invention.

Fig. 10 is a schematic view of the structure of the battery panel of the present invention.

Reference numerals in the drawings: 1. a conveying section; 11. a feed transport module; 111. a support frame; 112. a support ring; 113. a material guide plate; 12. a pushing and conveying module; 121. a tripod; 122. a material guiding strip; 123. a pushing plate; 124. a getter pump; 125. a pushing cylinder; 126. a material limiting transverse plate; 127. a turning plate; 13. a stacker transport module; 131. a motion frame; 132. a sponge cushion; 2. a cutting section; 21. a cutting frame; 22. a dust collection pump; 23. a receiving box; 24. adjusting a cylinder; 25. an execution rack; 26. driving a screw rod; 27. adjusting a motor; 28. a movable seat; 29. an auxiliary motor; 20. a limit rod; 201. a cutting seat; 202. a cutting head; 203. a cross bar; 204. executing a motor; 205. a material pumping pipe; 211. executing a telescopic rod; 212. a limiting ring; 213. a positioning rod; 214. rubber bumps; 215. a limit frame; 3. a polishing part; 31. a polishing frame; 32. a propulsion cylinder; 33. a lifting frame; 34. a limiting separator; 35. a working motor; 36. a threaded rotating rod; 37. a guide wheel; 38. polishing head; 39. and (5) a mobilizing frame.

Detailed Description

Referring to fig. 1 and 10 in combination, a cutting device for processing a hydrogen fuel cell plate includes: a conveying part 1 for conveying the battery plate, a cutting part 2 for grooving and cutting the outer wall of the battery plate and a polishing part 3 for polishing the slotted hole of the outer wall of the battery plate; the conveying part 1 comprises a feeding conveying module 11, a pushing conveying module 12 and a stacking conveying module 13; the upper end that is located feeding and transporting module 11 is provided with cutting part 2, and the left end that feeding and transporting module 11 is provided with pushing and transporting module 12, and the left side that is located pushing and transporting module 12 is provided with the portion of polishing 3, and the left side that is located the portion of polishing 3 is provided with the windrow and transports module 13.

During specific work, through placing the panel in proper order on feeding transport module 11, when the panel that waits to process moves under cutting part 2, offers the runner through cutting part 2 to it, accomplishes the follow-up transportation and carries on module 12 to push away, carries module 12 to push up it and keeps standing the state after polishing the runner through polishing part 3, carries module 13 to carry to appointed position through pushing away to carry module 12 to carry it to carry and collect after accomplishing at last.

Referring to fig. 1 and 2 in combination, the feeding and conveying module 11 includes a supporting frame 111, and a conveying belt is disposed inside the supporting frame 111; a supporting ring 112 is arranged on the inner wall of the supporting frame 111, and the supporting ring 112 is positioned inside the conveying belt; the upper end of the support frame 111 is symmetrically provided with a material guide plate 113, the right end of the material guide plate 113 is of an outward expansion structure, and rollers are movably arranged on the inner walls of the flaring of the two material guide plates 113, which are close to each other.

When the feeding is carried, the correction of the position of the battery plate is ensured through the action of the material guide plate 113, the position deflection of the battery plate is prevented, and the roller arranged improves the smooth transportation of the battery plate.

Referring to fig. 3 and 5 in combination, the cutting portion 2 includes a cutting frame 21 above a supporting frame 111; the upper end of the cutting frame 21 is provided with a dust suction pump 22, and the upper end of the cutting frame 21 is provided with a material collecting box 23; the discharging pipe of the dust suction pump 22 is positioned in the material receiving box 23; an adjusting cylinder 24 is arranged in the middle of the inner wall of the upper end of the cutting frame 21, and spring rods are uniformly arranged on the outer side of the adjusting cylinder 24 on the cutting frame 21; the movable ends of the spring rods are commonly connected with an execution frame 25, and the telescopic ends of the adjusting cylinders 24 are connected with the execution frame 25; two symmetrical driving lead screws 26 are arranged in parallel in the execution frame 25, and the driving lead screws 26 are connected with the execution frame 25 through bearings; one end of the driving screw rod 26 passes through the actuating frame 25 and is positioned at the outer side of the actuating frame 25, and one end of the driving screw rod 26 positioned at the outer side of the actuating frame 25 is provided with a belt wheel; an adjusting motor 27 is arranged at the position on the same side of the actuating frame 25 as the belt pulley through a motor seat, and the output shaft of the adjusting motor 27 is also provided with the belt pulley; the three belt wheels are positioned on the same straight line, and the three belt wheels are connected together through the toothed belt.

Referring to fig. 7 and 8 in combination, the cutting portion 2 further includes moving seats 28 respectively disposed on the driving screw 26 in a threaded connection manner, a transverse screw is disposed between the two moving seats 28 in a rotating manner, an auxiliary motor 29 is disposed on one of the moving seats 28, and an output shaft of the auxiliary motor 29 is fixedly connected with one end of the transverse screw; a limiting rod 20 is also arranged between the two movable seats 28, a cutting seat 201 is arranged on the limiting rod 20 in a sliding manner, the cutting seat 201 is in threaded connection with the transverse screw rod, and a cutting head 202 is rotatably arranged in the cutting seat 201; the bevel gear is arranged at one end of the cutting head 202, which is positioned in the cutting seat 201, the cross rod 203 is also arranged on the cutting seat 201 through a bearing, the bevel gear is also arranged at one end of the cross rod 203, which is close to the inside of the cutting seat 201, and the two bevel gears are meshed with each other; one end of the cross rod 203, which is positioned outside the cutting seat 201, is also provided with a belt wheel; the top end of the cutting seat 201 is provided with an execution motor 204 through a motor seat, the execution motor 204 is also provided with a belt wheel, and the belt wheel on the cross rod 203 is also connected with the belt wheel on the execution motor 204 through a belt; a material extracting pipe 205 is obliquely arranged in the cutting seat 201 at a position close to the cutting head 202; the suction pipe of the suction pump 22 is located inside the cutting seat 201 and connected to the suction pipe 205.

Referring to fig. 5 and 6 in combination, the cutting part 2 further includes an actuating telescopic rod 211 uniformly installed at the lower end of the actuating frame 25; a limiting ring 212 is arranged on the outer wall of the middle part of the telescopic rod of the execution telescopic rod 211, and positioning rods 213 are uniformly arranged on the limiting ring 212 in a rotating mode; the lower extreme of locating lever 213 is provided with rubber lug 214, is located the flexible end circumference outer wall of execution telescopic link 211 and evenly articulates and be provided with the regulation telescopic link, adjusts the flexible end and the locating lever 213 one-to-one of telescopic link, and adjusts the flexible end and be connected with locating lever 213 of telescopic link.

Referring to fig. 3, a limiting frame 215 is fixedly mounted at the lower end of the actuating frame 25 through a spring rod, and the limiting frame 215 is located below the rubber bump 214.

When the panel moves directly under the actuating rack 25; the actuating frame 25 is driven to wholly descend through the operation of the adjusting air cylinder 24, the limiting frame 215 is used for sleeving the battery plate inside, and the rubber convex blocks 214 are abutted against the conveying belt to continuously press down after passing through holes on the corresponding battery plate along with the continuous descending of the adjusting air cylinder 24 until the uniformly arranged positioning rods 213 are unfolded to fixedly abut against the hole walls of the battery plate; the relative movement is prevented in the process of grooving the surface of the battery plate, so that the opening effect of the flow channel on the surface of the battery plate is further ensured; and after the battery plate is limited and fixed; the cutting head 202 is driven to rotate to groove the surface of the battery plate by starting the execution motor 204, and the cutting head 202 is adjusted to move to any position by the combined action of the adjusting motor 27 and the auxiliary motor 29 to finish the grooving process; during the grooving process, the dust suction pump 22 always works to collect the scraps in the material receiving box 23 through the material suction pipe 205; the cutting part 2 that sets up can carry out the location spacing of a plurality of times to the in-process of seting up the runner to the panel surface, guarantees the stability of panel fluting in-process, prevents effectively that the runner of seting up from taking place the skew.

Referring to fig. 3 and fig. 4 in combination, the pushing and transporting module 12 includes a tripod 121 mounted at the left end of the supporting frame 111, and an inclined turning plate 127 is mounted on the tripod 121; square holes are formed in the material turning plates 127, and material guide strips 122 are arranged on the material turning plates 127 positioned on two sides of the square holes; the inner wall of the lower end of the square hole is provided with a pushing plate 123 in a hinged manner, air holes are uniformly formed in the pushing plate 123, an air suction pump 124 is arranged on the pushing plate 123, the air suction pump 124 is communicated with the air holes, a pushing cylinder 125 is hinged on the supporting frame 111, and the top end of the pushing cylinder 125 is hinged with the pushing plate 123; a material limiting transverse plate 126 is arranged on the material guiding plate 113 at the lower end of the square hole; the width of the pushing plate 123 is smaller than the width of the panel to be processed, so that when the panel is pushed up to be kept in an upright state after being adsorbed and fixed on the pushing plate 123, both sides of the panel can be inserted into corresponding positions inside the grinding part 3.

After the surface flow channel of the battery plate is opened, the battery plate is continuously conveyed to the pushing conveying module 12 through the feeding conveying module 11, then the battery plate is fixedly adsorbed on the pushing plate 123 through the operation of the suction pump 124, and then the pushing plate 123 is pushed by the pushing cylinder 125 to keep the vertical state so as to facilitate the polishing treatment of the polishing part 3 on the flow channel.

Referring to fig. 1, 4 and 9 in combination, the polishing section 3 includes a polishing frame 31 installed between the pushing and transporting modules 12 and 13; a pushing cylinder 32 is arranged on the inner wall of the top end of the polishing frame 31, a lifting frame 33 is arranged on two sides of the polishing frame 31 in a sliding manner, and the telescopic end of the pushing cylinder 32 is connected with the lifting frame 33; the lifting frame 33 is of a frame structure, a limiting partition 34 is arranged at an opening of the lifting frame 33, the inner wall of the frame of the lifting frame 33 is of an inclined structure, vertical downward sliding grooves are uniformly formed in the inner wall of the frame of the lifting frame 33 from front to back, a working motor 35 is arranged at the upper end of the lifting frame 33 in a sliding mode through a motor seat, a threaded rotating rod 36 is arranged on an output shaft of the working motor 35, the lower end of the threaded rotating rod 36 is arranged on the inner wall of the bottom end of the lifting frame 33 in a sliding mode through a sliding block, and the threaded rotating rod 36 is connected with the sliding block through a bearing; the outer wall threaded connection of screw thread bull stick 36 has the transfer frame 39, and transfer frame 39 slidable mounting is in the inside of crane 33, the lateral wall of transfer frame 39 evenly be provided with leading wheel 37, leading wheel 37 be located the spout inside, transfer frame 39 is type structure, and the inside of transfer frame 39 is through the even grinding head 38 of installing of bolt.

The method specifically comprises the steps of polishing a runner on the surface of a battery plate; the lifting frame 33 is controlled to descend through the pushing cylinder 32 to clamp the battery plate between the limiting partition 34 and the side wall of the lifting frame 33, then the threaded rotating rod 36 is driven to rotate through the working motor 35 to enable the transferring frame 39 to descend, and due to the fact that the inner wall of the frame body of the lifting frame 33 is of an inclined structure, the transferring frame 39 is affected by the guide wheel 37 and the inner wall of the frame body when descending, the lifting frame 33 integrally approaches the battery plate, further the polishing head 38 is inserted into a corresponding runner, and the polishing head 38 is driven to polish the battery plate when the transferring frame 39 integrally descends, so that smoothness of the runner of the battery plate is guaranteed; specifically, when the battery plate runner is polished, the polishing heads 38 can be arranged according to the distance between adjacent runners on the battery plate, which is set in advance, so that the positions of the adjacent polishing heads 38 on the mobilization frame 39 are in one-to-one correspondence with the runners; the polishing part 3 can ensure that the inner wall of the flow channel on the battery plate is even and smooth, and prevents the rough inner wall of the flow channel of the battery plate from influencing the reaction of substances such as gas and the like; the grinding part 3 can limit the battery plate when grinding the battery plate, so that the battery plate is prevented from shaking, and the adaptability of the battery plate to a battery plate flow channel is improved by adopting the row of adjustable grinding heads 38; and the processing treatment of various battery boards is convenient.

Referring to fig. 2 in combination, the stacker transport module 13 includes a moving frame 131, a conveyor belt disposed on the moving frame 131, and a foam-rubber cushion 132 disposed on the conveyor belt.

When the panel runner is polished, the pushing cylinder 32 controls the lifting frame 33 to retract so that the lifting frame 33 is separated from the panel, then the pushing cylinder 125 continues to push the pushing plate 123 to turn over and move the panel to the position above the foam-rubber cushion 132, then the suction pump 124 stops adsorbing the panel, and the panel falls on the foam-rubber cushion 132, is continuously conveyed to a set position by the conveyor belt and is collected.

The invention also provides a processing method of the hydrogen fuel cell plate, which comprises the following steps: s1: firstly, the battery plates to be processed are sequentially placed on the feeding conveying module 11 in sequence manually to be conveyed, and when the battery plates are conveyed to the position right below the cutting part 2, the battery plates are limited through the cutting part 2 and are sequentially processed and grooved.

S2: after the surface grooving processing of the battery plate is finished; the cutting part 2 is separated from the current battery plate and continues to grooving the next conveyed battery plate, and the grooved battery plate continues to be conveyed to the position of the pushing and conveying module 12 and is pushed up to keep an upright state after being adsorbed and fixed by the cutting part; the slot holes are then polished by the polishing section 3.

S3: after the slotted holes of the slotted battery plates are polished, the slotted holes are separated from the current battery plates through the polishing parts 3, the battery plates are continuously pushed onto the stacking transport module 13 through the pushing transport module 12, and then the battery plates are transported to a specified position through the stacking transport module 13 for collection.

The foregoing description is only illustrative of the present invention and is not intended to limit the scope of the invention, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present invention.

Claims (5)

1. A cutting device for processing a hydrogen fuel cell plate, comprising: a conveying part (1) for conveying the battery plate, a cutting part (2) for grooving and cutting the outer wall of the battery plate and a polishing part (3) for polishing the slotted hole of the outer wall of the battery plate; the method is characterized in that: the conveying part (1) comprises a feeding conveying module (11), a pushing conveying module (12) and a stacking conveying module (13); the upper end of the feeding conveying module (11) is provided with a cutting part (2), the left end of the feeding conveying module (11) is provided with a pushing conveying module (12), the left side of the pushing conveying module (12) is provided with a polishing part (3), and the left side of the polishing part (3) is provided with a stacking conveying module (13); wherein:

the feeding and conveying module (11) comprises a supporting frame (111), and the cutting part (2) comprises a cutting frame (21) positioned above the supporting frame (111); the upper end of the cutting frame (21) is provided with a dust suction pump (22), and the upper end of the cutting frame (21) is provided with a receiving box (23); the discharging pipe of the dust suction pump (22) is positioned in the material receiving box (23); an adjusting cylinder (24) is arranged in the middle of the inner wall of the upper end of the cutting frame (21), and spring rods are uniformly arranged on the outer side of the adjusting cylinder (24) on the cutting frame (21); the movable ends of the spring rods are commonly connected with an execution frame (25), and the telescopic ends of the adjusting cylinders (24) are connected with the execution frame (25); two symmetrical driving lead screws (26) are arranged in parallel in the execution frame (25), and the driving lead screws (26) are connected with the execution frame (25) through bearings; one end of the driving screw rod (26) passes through the execution frame (25) and is positioned at the outer side of the execution frame (25), and a belt wheel is arranged at one end of the driving screw rod (26) positioned at the outer side of the execution frame (25); an adjusting motor (27) is arranged at the position, on the same side as the belt wheel, of the actuating frame (25) through a motor seat, and the output shaft of the adjusting motor (27) is also provided with the belt wheel; the three belt wheels are positioned on the same straight line and are connected together through toothed belts;

the cutting part (2) further comprises moving seats (28) which are respectively arranged on the driving screw rods (26) in a threaded connection mode, a transverse screw rod is arranged between the two moving seats (28) in a rotating mode, an auxiliary motor (29) is arranged on one of the moving seats (28), and an output shaft of the auxiliary motor (29) is fixedly connected with one end of the transverse screw rod; a limiting rod (20) is also arranged between the two movable seats (28), a cutting seat (201) is arranged on the limiting rod (20) in a sliding manner, the cutting seat (201) is in threaded connection with the transverse screw rod, and a cutting head (202) is rotatably arranged in the cutting seat (201); bevel gears are arranged at one end, located inside the cutting seat (201), of the cutting head (202), a cross rod (203) is further arranged on the cutting seat (201) through a bearing, bevel gears are also arranged at one end, close to the inside of the cutting seat (201), of the cross rod (203), and the two bevel gears are meshed with each other; one end of the cross rod (203) positioned outside the cutting seat (201) is also provided with a belt wheel; an execution motor (204) is arranged at the top end of the cutting seat (201) through a motor seat, a belt wheel is also arranged on the execution motor (204), and the belt wheel on the cross rod (203) is also connected with the belt wheel on the execution motor (204) through a belt; a material suction pipe (205) is obliquely arranged in the cutting seat (201) at a position close to the cutting head (202); the suction pipe of the dust suction pump (22) is positioned in the cutting seat (201) and is connected with the suction pipe (205);

the cutting part (2) also comprises an execution telescopic rod (211) which is uniformly arranged at the lower end of the execution frame (25); a limiting ring (212) is arranged on the outer wall of the middle part of the telescopic rod of the execution telescopic rod (211), and positioning rods (213) are uniformly arranged on the limiting ring (212) in a rotating mode; the lower end of the positioning rod (213) is provided with a rubber lug (214), the outer wall of the circumference of the telescopic end of the execution telescopic rod (211) is uniformly hinged with an adjusting telescopic rod, the telescopic ends of the adjusting telescopic rod are in one-to-one correspondence with the positioning rod (213), and the telescopic ends of the adjusting telescopic rod are connected with the positioning rod (213);

the lower end of the execution frame (25) is fixedly provided with a limit frame (215) through a spring rod, and the limit frame (215) is positioned below the rubber lug (214);

the polishing part (3) comprises a polishing frame (31) arranged between the pushing and conveying module (12) and the stacking and conveying module (13); a pushing cylinder (32) is arranged on the inner wall of the top end of the polishing frame (31), a lifting frame (33) is arranged on the two sides of the polishing frame (31) in a sliding mode, and the telescopic end of the pushing cylinder (32) is connected with the lifting frame (33); the lifting frame (33) is of a frame structure, a limiting partition plate (34) is arranged at an opening of the lifting frame (33), the inner wall of the frame of the lifting frame (33) is of an inclined structure, vertical downward sliding grooves are uniformly formed in the inner wall of the frame of the lifting frame (33) from front to back, a working motor (35) is arranged at the upper end of the lifting frame (33) in a sliding mode through a motor seat, a threaded rotating rod (36) is arranged on an output shaft of the working motor (35), the lower end of the threaded rotating rod (36) is arranged on the inner wall of the bottom end of the lifting frame (33) in a sliding mode through a sliding block, and the threaded rotating rod (36) is connected with the sliding block through a bearing; the outer wall threaded connection of screw thread bull stick (36) has and moves frame (39), and moves the inside of frame (39) slidable mounting at crane (33), the lateral wall that moves frame (39) evenly be provided with leading wheel (37), leading wheel (37) be located the spout inside, move frame (39) and be type structure, and move the inside of frame (39) and evenly install polishing head (38) through the bolt.

2. The cutting device for processing a hydrogen fuel cell plate according to claim 1, wherein: a conveying belt is arranged in the supporting frame (111); a supporting ring (112) is arranged on the inner wall of the supporting frame (111), and the supporting ring (112) is positioned in the conveyer belt; the upper end of the support frame (111) is symmetrically provided with a material guide plate (113), the right end of the material guide plate (113) is of an outward expansion structure, and the inner walls of flaring which are mutually close to the two material guide plates (113) are movably provided with rollers.

3. The cutting device for processing a hydrogen fuel cell plate according to claim 1, wherein: the pushing and conveying module (12) comprises a tripod (121) arranged at the left end of the supporting frame (111), and an inclined turning plate (127) is arranged on the tripod (121); square holes are formed in the material turning plates (127), and material guide strips (122) are arranged on the material turning plates (127) positioned on two sides of the square holes; the inner wall of the lower end of the square hole is provided with a pushing plate (123) in a hinging manner, air holes are uniformly formed in the pushing plate (123), a suction pump (124) is arranged on the pushing plate (123), the suction pump (124) is communicated with the air holes, a pushing cylinder (125) is arranged on the supporting frame (111) in a hinging manner, and the top end of the pushing cylinder (125) is hinged with the pushing plate (123); a material limiting transverse plate (126) is arranged on the material guiding plate (113) at the lower end of the square hole.

4. The cutting device for processing a hydrogen fuel cell plate according to claim 1, wherein: the stacker transport module (13) comprises a moving frame (131), a conveyor belt is arranged on the moving frame (131), and a sponge cushion (132) is arranged on the conveyor belt.

5. The cutting device for processing a hydrogen fuel cell plate according to claim 1, wherein: the processing method of the cutting device for processing the hydrogen fuel cell plate comprises the following steps:

s1: firstly, manually placing the battery plates to be processed on a feeding conveying module (11) in sequence for conveying, limiting the battery plates by the cutting part (2) and sequentially processing and grooving when the battery plates are conveyed to the position right below the cutting part (2);

s2: after the surface grooving processing of the battery plate is finished; the cutting part (2) is separated from the current battery plate and is used for continuously grooving the next conveyed battery plate, and the grooved battery plate is continuously conveyed to the position of the pushing and conveying module (12) and is pushed up to be in an upright state after being adsorbed and fixed by the cutting part; then polishing the slot hole on the upper part through a polishing part (3);

s3: after the slotted holes of the slotted battery plates are polished, the slotted holes are separated from the current battery plates through the polishing parts (3), the battery plates are continuously pushed onto the stacking conveying module (13) through the pushing conveying module (12), and then the battery plates are conveyed to a specified position through the stacking conveying module (13) for collection.