CN115072393A - Mica plate production system for new energy automobile - Google Patents

Abstract

The invention discloses a mica plate production system for a new energy automobile, which comprises: the mica plate stacking mechanism comprises a first mounting frame, a slide rail is arranged on the first mounting frame along the length direction of the first mounting frame, a sliding support is movably mounted on the slide rail, a mica plate stacking platform is further arranged on the first mounting frame, the top surface of the mica plate stacking platform is a placing plane for placing mica plates, clamping mechanisms are arranged on two sides of the sliding support, and the clamping mechanisms can move to the position above the placing plane along with the sliding support; the paper cutting mechanism is arranged at the first end of the plate stacking mechanism and is used for cutting mica paper; and the placing platform is arranged at the second end of the plate stacking mechanism and is used for placing the glass fiber cloth. The invention can improve the processing efficiency of the mica plate.

Description

Mica plate production system for new energy automobile

Technical Field

The invention relates to the technical field of mica plates of new energy automobiles, in particular to a mica plate production system for a new energy automobile.

Background

When a lithium battery cell is selected, the safety, the endurance mileage and the charge and discharge performance of the new energy automobile powered by the lithium battery cell need to be considered. Generally speaking, high energy density and high charge-discharge performance's electric core has higher emergence heat to spread the risk usually, and prior art generally adopts the mica plate to insulate against heat, need carry out compound stack with multilayer mica paper in the course of working of mica plate, and mica paper generally is a book setting, and it is convoluteed on the tube core, adopts manual superimposed mode among the prior art, and its intensity of labour is big, influences machining efficiency moreover, is unfavorable for realizing automated production.

Disclosure of Invention

The invention provides a mica plate production system for a new energy automobile, which can improve the processing efficiency of mica plates.

In order to solve the above technical problem, the present invention provides a mica plate production system for a new energy automobile, including:

the plate stacking mechanism comprises a first mounting frame, a slide rail is arranged on the first mounting frame along the length direction of the first mounting frame, a sliding support is movably mounted on the slide rail, a plate stacking platform is further arranged on the first mounting frame, the top surface of the plate stacking platform is a placing plane for placing mica plates, clamping mechanisms are arranged on two sides of the sliding support, and the clamping mechanisms can move to the position above the placing plane along with the sliding support;

the paper cutting mechanism is arranged at the first end of the plate stacking mechanism and is used for cutting mica paper;

and the placing platform is arranged at the second end of the plate stacking mechanism and is used for placing the glass fiber cloth.

Preferably, as for the above technical solution, the paper cutting mechanism includes a second mounting frame, a conveying belt, a conveying mechanism and a paper cutting machine head are arranged on the second mounting frame, the conveying belt is used for contacting with the mica paper, a rotating roller is arranged on the second mounting frame, the conveying belt is driven by the rotating roller, the conveying mechanism is used for driving the mica paper to move, the paper cutting machine head at least includes a paper cutting tool, a transverse slide rail and a tool driving mechanism, the transverse slide rail is arranged along the width direction of the second mounting frame, the paper cutting tool is movably arranged on the transverse slide rail, and the tool driving mechanism is connected with the paper cutting tool and is used for driving the paper cutting tool to move along the transverse slide rail.

Preferably, the placing platform comprises a third installation frame, and a fiberglass cloth platform is arranged on the third installation frame.

Preferably, as for the above technical solution, one end of the third installation frame close to the plate stacking mechanism is provided with a glass fiber cloth conveying mechanism.

Preferably, the third mounting frame is further provided with a blowing mechanism.

Preferably, the glass fiber cloth conveying mechanism comprises a driving roller, the driving roller is connected with a driving motor, the driving roller is located above the glass fiber cloth platform, the blowing mechanism is arranged above the driving roller, and a blowing port of the blowing mechanism faces the driving roller.

Preferably, the drive roll is provided with a toothed member, the toothed member is made of rubber, and teeth are arranged on the surface of the toothed member.

Preferably, a driven roller is disposed below the driving roller, the driven roller is close to the plate stacking mechanism relative to the driving roller, and the driven roller is rotatably mounted on the third mounting frame.

Preferably, a rubber layer is provided on a surface of the driven roller.

Preferably, the first installation frame is provided with a vertical rail along a vertical direction, the glass fiber cloth platform is movably arranged on the vertical rail, and the glass fiber cloth platform is connected with the vertical driving mechanism.

The invention provides a mica plate production system for a new energy automobile, which comprises a plate stacking mechanism, a paper cutting mechanism and a placing platform, wherein the plate stacking mechanism at least comprises a first mounting frame, a slide rail is arranged on the first mounting frame along the length direction, a slide support is arranged on the slide rail, the plate stacking platform is arranged on the first mounting frame, the top surface of the plate stacking platform is a placing plane for placing mica plates, clamping mechanisms are arranged on two sides of the slide support, the paper cutting mechanism is arranged at the first end of the plate stacking mechanism, the placing platform is arranged at the second end of the plate stacking mechanism, the slide support can move towards the first direction to be close to the paper cutting mechanism, the slide support can also move towards the second direction to be close to the placing platform, the mica paper is firstly cut into a set size by the paper cutting mechanism during working, then the slide support moves towards the first direction to enable the clamping mechanism to be close to the mica paper, be located the one end that is close to the fixture centre gripping mica paper of mica paper one side, then remove to the top of folded plate platform, loosen fixture and make the mica paper arrange in on the folded plate platform, the fine cloth of glass has been placed on the place the platform, then continue to move towards second direction and make fixture be close to the fine cloth of glass near the place the platform, the fixture centre gripping that is located near fine cloth one side of glass holds the fine cloth of glass and moves to the top of folded plate platform towards first direction, loosen fixture and make the fine cloth of glass arrange in on the mica paper, in proper order the repeated board folding work of accomplishing, it can promote work efficiency greatly.

The foregoing description is only an overview of the technical solutions of the present invention, and the embodiments of the present invention are described below in order to make the technical means of the present invention more clearly understood and to make the above and other objects, features, and advantages of the present invention more clearly understandable.

Drawings

Fig. 1 shows a front view of a mica board production system for a new energy automobile according to an embodiment of the present invention;

FIG. 2 shows a top view of FIG. 1;

FIG. 3 is a schematic perspective view of a placement platform according to an embodiment of the invention;

FIG. 4 is a schematic perspective view of a paper cutting mechanism according to an embodiment of the present invention;

FIG. 5 is a schematic perspective view of a paper cutting mechanism according to an embodiment of the present invention;

FIG. 6 is a schematic perspective view of a guillotine head according to an embodiment of the invention;

FIG. 7 is a schematic perspective view of a guillotine head according to an embodiment of the invention;

FIG. 8 shows an enlarged schematic view at A in FIG. 6;

FIG. 9 is a schematic perspective view of a plate stacking mechanism according to an embodiment of the present invention;

FIG. 10 shows a front view of a plate stacking mechanism in an embodiment of the invention;

FIG. 11 shows a top view of a plate stacking mechanism in an embodiment of the invention;

FIG. 12 shows a schematic view of the structure of the chucking mechanism in the embodiment of the present invention;

FIG. 13 is a schematic perspective view of a glue application mechanism in an embodiment of the invention;

FIG. 14 is a schematic plan view of the glue applying mechanism in the embodiment of the present invention;

fig. 15 is a schematic plan view illustrating an automatic unwinding device according to an embodiment of the present invention;

FIG. 16 is a schematic perspective view of a device body according to an embodiment of the present invention;

FIG. 17 shows an enlarged schematic view at A in FIG. 15;

FIG. 18 is a schematic plan view showing the tube discharging mechanism in the embodiment of the present invention;

fig. 19 is a schematic perspective view of a pipe discharging mechanism in an embodiment of the invention.

Detailed Description

In order to make the objects, features and advantages of the present invention more obvious and understandable, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 19, an embodiment of the present invention provides a mica plate production system for a new energy automobile, including:

the plate stacking mechanism 40 comprises a first installation rack 401, a sliding rail 402 is arranged on the first installation rack 401 along the length direction of the first installation rack 401, a sliding support 407 is movably installed on the sliding rail 402, a plate stacking platform 405 is further arranged on the first installation rack 401, the top surface of the plate stacking platform 405 is a placing plane for placing mica plates, clamping mechanisms 408 are arranged on two sides of the sliding support 407, and the clamping mechanisms 408 can move to the position above the placing plane along with the sliding support 407;

the paper cutting mechanism 30 is arranged at the first end of the plate stacking mechanism 40, and the paper cutting mechanism 30 is used for cutting mica paper;

and the placing platform 50 is arranged at the second end of the plate stacking mechanism, and the placing platform 50 is used for placing the glass fiber cloth.

In a further implementation manner of this embodiment, the paper cutting mechanism includes a second mounting frame 301, a conveying belt 303, a conveying mechanism, and a paper cutter head 307 are disposed on the second mounting frame 301, the conveying belt 303 is configured to contact with mica paper, a rotating roller 306 is disposed on the second mounting frame 301, the conveying belt 303 is driven by the rotating roller 306, the conveying mechanism is configured to drive the mica paper to move, the paper cutter head 307 at least includes a paper cutter 3073, a transverse slide rail 3071, and a cutter driving mechanism 3075, the transverse slide rail 3071 is disposed along a width direction of the second mounting frame 301, the paper cutter 3073 is movably disposed on the transverse slide rail 3073, and the cutter driving mechanism 3075 is connected with the paper cutter 3073 and is configured to drive the paper cutter 3073 to move along the transverse slide rail 3073.

The mica plate production system for the new energy automobile comprises a plate stacking mechanism 40, a paper cutting mechanism 30 and a placing platform 50, wherein the plate stacking mechanism 40 at least comprises a first mounting frame 401, a sliding rail 402 is arranged on the first mounting frame 401 along the length direction, a sliding support 407 is arranged on the sliding rail 402, the first mounting frame 401 is provided with a plate stacking platform 405, the top surface of the plate stacking platform 405 is a placing plane for placing mica plates, two sides of the sliding support 407 are respectively provided with a clamping mechanism 408, the paper cutting mechanism 30 is arranged at a first end of the plate stacking mechanism 40, the placing platform 50 is arranged at a second end of the plate stacking mechanism 40, the sliding support 407 can move towards the paper cutting mechanism 30 in a first direction, the sliding support can also move towards the placing platform 50 in a second direction, and when the mica plate stacking mechanism works, the paper cutting mechanism 30 firstly cuts mica paper into a set size, then sliding support 407 moves towards first direction and makes fixture 408 be close to the mica paper, the fixture 408 that is located near mica paper one side centre gripping mica paper's one end, then move to the top of folding board platform 405, unclamp fixture 408 and make the mica paper arrange in on folding board platform 405, the fine cloth of glass has been placed on place platform 50, then continue to move towards second direction and be close to place platform and make fixture be close to the fine cloth of glass, the fixture that is located near fine cloth of glass one side centre gripping fine cloth of glass moves to the top of folding board platform towards first direction, unclamp fixture makes the fine cloth of glass arrange in on the mica paper, repeat completion folding board work in proper order, it can promote work efficiency greatly.

In a further implementation of this embodiment, the placing platform includes a third mounting frame 501 on which a fiberglass cloth platform 502 is disposed.

In this embodiment, the glass fiber cloth holder is placed on the glass fiber cloth platform 502, and specifically, a plurality of pieces of glass fiber cloth with a set size are stacked on the glass fiber cloth platform 502.

In a further implementation manner of this embodiment, one end of the third installation frame 501 close to the stacking mechanism 40 is provided with a fiberglass cloth conveying mechanism 503.

Glass fiber cloth conveying mechanism can mutually support work with fixture 408 in this embodiment, particularly, need drive through glass fiber cloth conveying mechanism 503 before fixture 408 centre gripping and make the glass fiber cloth that is located the superiors remove, particularly, for driving the glass fiber cloth and remove the tip protrusion third installation frame 501 that makes glass fiber cloth, it can be convenient for fixture 408 to carry out the centre gripping to glass fiber cloth.

In a further implementation manner of this embodiment, a blowing mechanism is further disposed on the third mounting frame 501.

The blowing mechanism in this embodiment is used for blowing to the fine cloth of glass who is located the superiors when carrying fine cloth of glass, because fine cloth material light and soft characteristic of glass, it can't keep level at the in-process of carrying, and the blowing mechanism can be used for being located the fine cloth of glass of superiors and blow for it keeps the leveling state in transportation process.

Specifically, the blower mechanism in this embodiment includes a blower mounting bracket 506 and a blower (not shown in the figure) mounted on the blower mounting bracket 506.

In a further implementation manner of this embodiment, the glass fiber cloth conveying mechanism 503 includes a driving roller 504, the driving roller 504 is connected to the driving motor 507, the driving roller 504 is located above the glass fiber cloth platform 502, the blowing mechanism is disposed above the driving roller 504, and a blowing port of the blowing mechanism faces the driving roller 504.

In a further embodiment of the present embodiment, a tooth member 505 is disposed on the drive roller 504, the tooth member 505 is made of rubber, and teeth are disposed on the surface of the tooth member 505.

The glass fiber cloth conveying mechanism in the embodiment is simple in structure and stable in operation, the glass fiber cloth on the uppermost layer is conveniently driven, the driving roller rotates to drive the glass fiber cloth to move forwards in a contact mode, the blowing opening of the blowing mechanism faces the driving roller, the glass fiber cloth can be prevented from being rolled up by the driving roller, and the glass fiber cloth can be kept to move straightly and forwards.

In a further possible embodiment of the present embodiment, a driven roller 508 is provided below the drive roller 504, and the driven roller 508 is close to the stacker mechanism 40 with respect to the drive roller 504, and the driven roller 508 is rotatably mounted on the third mounting frame 501.

Driven voller and drive roll cooperation work in this embodiment, the driven voller is close to folded plate mechanism more moreover, and it can be so that the transport of glass fiber cloth is more stable.

In a further possible implementation of this embodiment, the surface of the driven roller 508 is provided with a rubber layer.

The rubber layer in this embodiment may increase the friction during contact.

In a further implementation manner of this embodiment, a vertical rail 509 is disposed on the first mounting frame 501 along the vertical direction, the fiberglass cloth platform 502 is movably disposed on the vertical rail 509, and the fiberglass cloth platform 502 is connected to the vertical driving mechanism.

The glass fiber cloth platform 502 in this embodiment can rise and fall in the vertical direction, and it can be convenient for adjust the height of glass fiber cloth platform, specifically speaking, after the glass fiber cloth of the superiors has been carried, the distance between profile component and the glass fiber cloth increases, can make the glass fiber cloth platform rise this moment, and it can make the glass fiber cloth of the superiors can keep in contact with the profile component all the time, and in addition, it can also adjust the pressure between profile component and the glass fiber cloth of the superiors, further promotes frictional force.

Referring to fig. 4 to 8, the paper cutting mechanism 30 of this embodiment includes a second mounting frame 301, a conveying mechanism and a paper cutter head 307, a conveying belt 303 is disposed on the second mounting frame 301, the conveying belt 303 is moved by a rotating roller 306, the paper cutter head 307 at least includes a paper cutter 3073, a transverse slide rail 3071 and a cutter driving mechanism 3075, when the paper cutter head is in operation, the mica paper is placed on the conveying belt 303, the conveying belt 303 and the conveying mechanism drive the mica paper to move forward, after the mica paper moves for a certain distance, the conveying belt 303 and the conveying mechanism stop working, the cutter driving mechanism 3075 drives the paper cutter 3073 to move transversely along the transverse slide rail 3071, and a cutting edge contacts with the mica paper during the transverse movement of the paper cutter 3073, which can cut the mica paper, can automatically complete the paper cutting operation, and can improve the efficiency of cutting the mica paper.

Specifically, the paper cutting tool 3073 in this embodiment is mounted on a tool holder 3072, the tool holder 3072 is a plate structure, the tool holder 3072 is movably mounted on the transverse slide rail 3071 through a sliding block, in addition, the tool driving mechanism 3075 in this embodiment includes a tool driving motor 3076 and a belt 3077, the belt 3077 may be a synchronous belt, a main shaft of the tool driving motor 3076 is mounted with a synchronous pulley, the tool holder 3072 is fixedly mounted on the belt 3077, it drives the paper cutting tool 3073 to move in the transverse direction of the second mounting frame 301 through the forward and reverse rotation of the tool driving motor 3076, and the conveyor belt 303 and the conveying mechanism in this embodiment drive the mica paper to move in the longitudinal direction of the second mounting frame 301.

In a further implementation manner of this embodiment, the second mounting frame 301 includes a lower bracket 3011 and an upper bracket 3012, the lower bracket 3011 is provided with a longitudinal slide rail along the length direction thereof, the lower bracket 3011 is movably mounted on the longitudinal slide rail 3013, and the conveying belt 303, the conveying roller 3081, the conveying mechanism, and the cutter head 307 are provided on the upper bracket 3012.

The upper support 3012 in this embodiment can move in its longitudinal direction with respect to the lower support 3011, and the conveyor belt 303, the conveyor roller 3081, the conveying mechanism, and the cutter head 307 are provided to the upper support 3012, so the cutter head 307 in this embodiment can move to a set position to cut the mica paper.

In addition, the second mounting frame 301 in this embodiment is further provided with a frame driving mechanism 310, the frame driving mechanism 310 is used for driving the upper frame 3012 to move relative to the lower frame 3011, specifically, the frame driving mechanism 310 may adopt a screw rod mechanism, which sets a screw rod nut on the upper frame 3012, and drives the upper frame 3012 to move along the length direction through the rotation of the screw rod.

In a further implementation manner of this embodiment, a pressing mechanism 304 is disposed on the second mounting frame 301, the pressing mechanism 304 includes a pressing support 3041, a pressing cylinder 3042 and a pressing plate 3043, the pressing support 3041 is disposed above the conveying belt 303, the pressing cylinder 3042 is mounted on the pressing support 3041, and a piston rod of the pressing cylinder 3042 is connected to the pressing plate 3043 for driving the pressing plate 3043 to move up and down.

The pressing mechanism 304 in this embodiment can press the mica paper when performing cutting work, so as to prevent the mica paper from displacing during the cutting process, specifically, when cutting is required, the pressing cylinder 3042 drives the pressing plate 3043 to move downward, so that the pressing plate 3043 presses on the mica paper, and after the cutting is completed, the pressing cylinder 3042 drives the pressing plate 3043 to abut upward, so that the pressing plate 3043 is separated from the mica paper.

Also, a hold-down bracket 3041 in this embodiment is mounted on the upper bracket 3012.

In a further embodiment of this embodiment, the upper support 3012 is provided with a movable slide 305 along its length direction, and the pressing support 3041 is movably mounted on the movable slide 305.

In this embodiment, since the pressing bracket 3041 is movably mounted on the movable slide 305, the pressing mechanism 304 can be adjusted in position relative to the upper bracket 3012.

In a further possible embodiment of this embodiment, the paper cutting mechanism further comprises a roller drive mechanism, and the roller drive mechanism 309 is connected to the rotating roller 306 for driving the rotating roller 306 to rotate.

The roller driving mechanism 309 in this embodiment is a roller driving motor, which is connected to the rotary roller 306 and is used to rotate the rotary roller 306, and specifically, the roller driving motor is provided on the upper bracket 3012.

In a further embodiment of this embodiment, the conveying mechanism includes a conveying roller 3081 and a conveying driving part 3079, the conveying roller 3081 is used for contacting with the lower surface of the mica paper, and the conveying driving part 3079 is used for driving the conveying roller 3081 to rotate.

In this embodiment, the conveying driving component 3079 drives the conveying roller 3081 to rotate, and the conveying roller 3081 can drive the mica paper to move forward.

In a further embodiment of this embodiment, a pinch roller mechanism 3078 is disposed above the conveyor roller 3081, and the pinch roller mechanism 3078 includes at least a pinch roller 3083, and the pinch roller 3083 is configured to contact the upper surface of the mica paper.

The pinch roller 3083 in this embodiment corresponds the setting with the conveyer roller 3081, and the pinch roller 3083 compresses tightly the upper surface at the mica paper, and the pinch roller 3083 takes place to rotate along with the mica paper, and it can make the transport of mica paper more stable with the cooperation of conveyer roller 3081.

In a further practical implementation manner of this embodiment, the paper cutting machine head 307 further includes a cutter support 3072, a mounting shaft 3089 is provided on the cutter support 3072, the paper cutting tool 3073 is a circular blade, the circular blade is sleeved on the mounting shaft 3089, a cutter spacer block 3088 is provided on the back of the circular blade, a pressing nut 3086 is provided on the mounting shaft 3089 in a threaded connection manner, a pressing spring 3087 is further sleeved on the mounting shaft 3089, and two ends of the pressing spring 3087 respectively exert elastic forces on the circular blade and the pressing nut 3086.

The circular blade in this embodiment can elastically move along the mounting shaft 3089, and specifically, the circumferential surface of the circular blade in this embodiment is a cutting edge.

Specifically, the paper cutting machine head 307 in this embodiment further includes a paper cutting support 3080, the paper cutting support 3080 is mounted on the upper support 3012 and transversely disposed along the upper support 3012, a transverse slide rail 3071 is transversely disposed on the paper cutting support 3080, the pressing wheel mechanism 3078 includes a pressing wheel support 3082, the pressing wheel support 3082 is connected with a threaded mounting plate 3085 through a connecting rod body, the threaded mounting plate 3085 is in threaded connection with the adjusting shaft 3084, the pressing wheel 3083 is rotatably mounted on the adjusting shaft 3084, and the pressing force of the pressing wheel 3083 can be further adjusted by adjusting the adjusting shaft 3084.

In a further embodiment of the present embodiment, the second mounting frame 301 is provided with a positioning plate 3074 along the width direction thereof, and the rear surface of the circular blade is in contact with the front end surface of the positioning plate 3074.

The circular blade in this embodiment can contact with the preceding terminal surface of locating plate 3074 all the time through top tight spring 3087, and it can keep the circular blade unanimous with locating plate 3074 all the time at the in-process that removes, promotes the cutting quality.

In a further possible implementation of the present embodiment, both ends of the second mounting frame 301 are provided with a first guide plate 302 and a second guide plate 308, respectively.

The first and second guide plates 302, 308 in this embodiment can facilitate the ingress and egress of mica paper.

Referring to fig. 9 to 12, in the embodiment, the plate stacking mechanism 40 includes a first mounting frame 401, a plate stacking platform 405, a sliding support 407 and a clamping mechanism 408, the first mounting frame 401 is provided with a sliding rail 402, the sliding support 407 is movably mounted on the sliding rail 402, so that the sliding support 407 can move on the sliding rail 402 along the length direction of the first mounting frame 401, the sliding support 407 is provided with a clamping mechanism 408, when the mica paper is moved to the plate stacking platform 405, one end of the mica paper is clamped by the clamping mechanism 408 and then moved towards the plate stacking platform 405, when the mica paper is moved to the plate stacking platform 405, the clamping mechanism 408 is released to place the mica paper on the plate stacking platform 405, then the mica paper is moved to an initial position again to clamp the mica paper, and then the next mica paper is clamped to stack the second mica paper on the first mica paper by moving, so that the reciprocating operation can automatically complete the plate stacking operation in the mica paper processing process, it can promote machining efficiency, reduces working strength.

In a further implementation manner of this embodiment, a through space 404 is provided at an intermediate position of the first installation frame 401, and the stacking platform 405 is located in the through space 404.

In this embodiment, the stacking platform 405 is disposed at a middle position of the first mounting frame 401, which can facilitate the stacking work, and in addition, the stacking platform 405 is disposed in the passing space 404, so that the overall structure is more compact.

In a further implementation manner of this embodiment, a vertical slide rail 410 is disposed on the first mounting frame 401 along the vertical direction, the stacking platform 405 is movably mounted on the vertical slide rail 410, the stacking platform 405 is connected to a lifting driving mechanism (not shown in the figure), and the lifting driving mechanism is mounted on the first mounting frame 401.

The stacking platform 405 in this embodiment can move up and down on the first mounting frame 401, and particularly, the stacking platform 405 can move up and down in the passing space 404, which can adjust the height of the stacking platform 405 according to the stacking process.

In a further implementation manner of the present embodiment, a pressure plate is disposed on the first mounting frame 401, and the pressure plate is located in the passing space 404 and above the plate stacking platform 405.

In this embodiment, a pressing plate is disposed above the stacking platform 405, and since the clamping mechanism 408 is in a dragging manner when carrying mica paper, when stacking mica paper, the mica paper on the stacking platform 405 may be displaced to cause misalignment of each layer of mica paper, so that in this embodiment, before the clamping mechanism 408 moves, the stacking platform 405 may rise under the driving of the lifting driving mechanism to press the pressing plate on the mica paper on the stacking platform 405, then the clamping mechanism 408 moves along the sliding rail 402 to drag the mica paper to the position above the stacking platform 405, and then the stacking platform 405 descends, and the clamping mechanism 408 releases the mica paper to complete stacking work.

Specifically, the pressing plate in this embodiment includes a first pressing plate 403 and a second pressing plate 406, the first pressing plate 403 and the second pressing plate 406 are respectively disposed at two side positions of the passing space 404, and the first pressing plate 403 and the second pressing plate 406 in this embodiment are thin plates fixed to the first mounting frame 401.

In a further alternative embodiment of this embodiment, the side of the sliding support 407 remote from the stacking platform 405 is provided with a plurality of clamping mechanisms 408.

In a further alternative embodiment of this embodiment, the side of the sliding support 407 adjacent to the stacking platform 405 is provided with a plurality of clamping mechanisms 408.

Because the middle filling material needs to be added between the two layers of mica paper when the mica paper is stacked, the two sides of the sliding support 407 in the embodiment are respectively provided with the plurality of clamping mechanisms 408 for clamping the mica paper and the middle filling material, so that the convenience of the plate stacking work is further improved.

In a further implementation of this embodiment, the clamping mechanism 408 includes a first clamping portion 4082, a second clamping portion 4083, and a driving cylinder 4081, the first clamping portion 4082 and the second clamping portion 4083 are parallel to each other, the first clamping portion 4082 is movably disposed relative to the second clamping portion 4083, and the first clamping portion 4082 is connected to the driving cylinder 4081.

In a further embodiment of the present embodiment, a surface of the first clamping portion 4082 close to the second clamping portion 4083 is provided with a soft material 4084.

In this embodiment in the time of work drive cylinder 4081 and drive first clamping part 4082 downstream with the mica paper centre gripping at first clamping part 4082 and second clamping part 4083, first clamping part 4082 and second clamping part 4083 in this embodiment are the plate body structure that is parallel to each other, fixture 408 simple structure and job stabilization in this embodiment, in addition, soft material 4084 can have anti-skidding effect, and can also protect the surface of mica paper.

In a further possible implementation of this embodiment, the front end of the first mounting frame 401 is provided with a guide plate 409.

The guide plate 409 in this embodiment is a thin plate structure that extends outward to facilitate guiding the mica paper into the holding mechanism 408.

In a further implementation manner of this embodiment, the number of the lead-in plates 409 is multiple, and the clamping mechanism 408 is located between two adjacent lead-in plates 409.

The positioning of the clamping mechanism 408 in this embodiment between two adjacent guide-in plates 409 may further facilitate the introduction of the mica paper between the first and second clamping portions 4082, 4083.

Referring to fig. 13 and 14, the mica plate production system for a new energy automobile of the present embodiment further includes a glue applying mechanism, where the glue applying mechanism includes:

a fourth mounting frame 201, a glue groove 210 is arranged on the fourth mounting frame 201, the glue groove 210 has a containing space for containing glue,

a glue roller 207 rotatably provided on the fourth mounting frame 201, at least a portion of the glue roller 207 being located in the accommodating space, the glue roller 207 being adapted to contact glue located in the accommodating space;

the flow guide component 203 is connected with the fourth installation rack 201, and a plurality of flow guide grooves 209 are formed in the flow guide component 203;

a glue applying scraper 206 disposed at a glue inlet position of the guide groove 209, the glue applying scraper 206 contacting with an outer circumferential surface of the glue applying roller 207;

the gluing cloth 205 is used for contacting the surface of the mica paper, and the gluing cloth 205 is arranged at the glue outlet position of the diversion trench 209;

and the driving motor 202 is connected with the sizing roller 207, and the driving motor 202 is used for driving the sizing roller 207 to rotate.

The embodiment provides a mica paper gluing mechanism for a new energy battery, which comprises a fourth mounting frame 201, a gluing roller 207, a flow guide part 203, a gluing scraper 206, a gluing cloth 205 and a driving motor 202, wherein a glue tank 210 is mounted on the fourth mounting frame 201, glue can be placed in the glue tank 210, the gluing roller 207 extends into the glue tank 210 and can be in contact with the glue in the glue tank 210, the flow guide part 203 is provided with a flow guide groove 209, the gluing scraper 206 is in contact with the circumferential surface of the gluing roller 207, the gluing scraper 206 is positioned at the gluing inlet position of the flow guide groove 209, the gluing cloth 205 is positioned at the gluing outlet position of the flow guide groove 209, when the gluing roller 207 is rotated by the driving motor 202, the gluing roller 207 can attach the glue in the glue tank 210 to the surface thereof, during the rotation, the gluing scraper 206 scrapes the glue on the surface of the gluing roller 207 and enables the glue to enter the flow guide groove 209 from the gluing inlet, and then, glue is guided to the glue applying cloth 205 through the glue applying outlet, the glue applying cloth 205 is contacted with the surface of the mica paper, and the glue is coated on the surface of the mica paper, so that the glue coating on the surface of the mica paper can be automatically finished, the glue coating quality is improved, the labor intensity can be reduced, and the working environment can be improved.

Specifically, the drive motor 202 in the present embodiment is connected to the glue roller 207 through a transmission mechanism, the glue roller 207 is mounted on the fourth mounting frame 201 through a rotating shaft, the upper end of the glue blade 206 in the present embodiment is in close contact with the surface of the glue roller 207, and the lower end of the glue blade 206 is aligned with the glue inlet of the guiding groove 209.

In a further embodiment of this embodiment, the guiding member 203 is provided with a driving member 215, the driving member 215 is connected to at least one end of the applying fabric 205, and the driving member 215 is used for driving one end of the applying fabric 205 to move along the length direction of the guiding groove 209.

In this embodiment, the application cloth 205 may be dragged by the driving member 215 to move along the guiding groove 209, which may facilitate the adjustment of the position of the application cloth 205, and the driving member 215 in this embodiment may employ a driving cylinder, and a piston rod of the driving cylinder is used for connecting with the application cloth 205.

In a further implementation manner of this embodiment, the driving member 215 is connected to the movable member 211, the first end of the glue applying cloth 205 is connected to the first rod 208, the movable member 211 is provided with a bayonet 212, and the first rod 208 is disposed in the bayonet 212.

The first rod 208 in this embodiment is placed directly in the bayonet 212, which may facilitate installation of the size cloth 205.

The movable part 211 in this embodiment is a block, and the bayonet 212 is a U-shaped opening provided on the block, and the block is connected with a piston rod of the cylinder.

In a further implementation of this embodiment, the air guide member 203 is detachably connected to the fourth mounting frame 201.

The air guide member 203 is detachably connected to the fourth mounting frame 201 in this embodiment, which facilitates the mounting and dismounting of the air guide member 203.

In a further implementation manner of this embodiment, the air guiding member 203 is fixedly installed on the installation rod 216, the fourth installation frame 201 is provided with an opening member 214, the opening member 214 is at least provided with an opening, the installation rod 216 is disposed in the opening, the opening member 214 is provided with a tightening bolt 213 in a threaded connection manner, and the tightening bolt 213 is tightened against the installation rod 216 so as to position the installation rod 216 in the opening.

In this embodiment, the installation rod body 216 is tightly pushed in the opening of the opening part 214 through the tightening bolt 213, which can further facilitate the installation and the disassembly of the diversion part 203, and in addition, it can also facilitate the angle adjustment of the diversion part 203, specifically, the installation rod body 216 in this embodiment is a hollow circular rod body, which can facilitate the angle adjustment, and the circular rod body is fixed on the back of the diversion part 203.

In a further implementation manner of this embodiment, an adjusting bolt 217 is screwed on the fourth mounting frame 201, and the adjusting bolt 217 is set on the back of the air guide member 203.

In this embodiment, the adjusting bolt 217 abuts against the back of the air guiding member 203, which can keep the air guiding member 203 at a set angle, and then the adjusting bolt 217 can be screwed to adjust the angle of the air guiding member 203.

In a further possible embodiment of this embodiment, the upper part of the glue cloth 205 covers the glue reservoir 210, and the lower end of the glue cloth 205 extends downwards around the glue outlet of the flow guide 209.

The upper portion of the glue applying cloth 205 in this embodiment covers the glue groove 210, which can prevent the glue from overflowing the flow guide groove 209, and in addition, the lower end of the glue applying cloth 205 extends downward around the glue outlet of the flow guide groove 209, so the glue applying cloth 205 can be attached to the glue outlet of the flow guide groove 209, which can facilitate the glue to flow onto the glue applying cloth 205.

In a further embodiment of this embodiment, the size cloth 205 covers the lower part of the flow guide grooves 209.

The glue groove 210 in this embodiment is covered by the glue cloth 205 at a portion near the lower end, and the glue groove 210 is exposed at a portion near the upper end, which not only prevents the glue from overflowing, but also facilitates the glue to flow onto the glue cloth 205.

In a further implementation manner of this embodiment, the guiding grooves 209 are obliquely disposed, the guiding component 203 is a plate structure, and a plurality of guiding grooves 209 are equidistantly distributed on the surface of the plate structure.

The arrangement of the flow guide grooves 209 in this embodiment can realize that the glue is uniformly attached to the glue applying cloth 205, and further, it can be convenient to realize that the glue is coated on the surface of the mica paper.

In a further implementation manner of this embodiment, the glue applying cloth 205 is a cloth cover structure, the first rod 208 is inserted into a hole of the glue applying cloth 205 of the cloth cover structure, the second rod 204 is further disposed in the hole, and the glue applying cloth 205 can bear the second rod 204 to make the glue applying cloth 205 fall downward.

The sizing cloth 205 in this embodiment is a cloth cover structure, which is more convenient for the arrangement of the first rod 208 and the second rod 204, and in addition, the second rod 204 can make the sizing cloth 205 fall downwards to keep the sizing cloth 205 attached to the sizing outlet of the guiding groove 209.

Referring to fig. 15 to 19, the mica plate production system for a new energy automobile of the present embodiment further includes an automatic unwinding device, and the automatic unwinding device includes:

the unwinding device comprises a device body 101, wherein the device body 101 is rotatably provided with at least two top pressing heads 108, the two top pressing heads 108 are correspondingly arranged at two ends of the unwinding tube core, at least one top pressing head 108 of the two top pressing heads 108 can move towards a first direction and a second direction relative to the other top pressing head 108, when the top pressing heads 108 move towards the first direction, the two top pressing heads 108 are close to each other, and when the top pressing heads 108 move towards the second direction, the two top pressing heads 108 are far away from each other;

the rotary driving piece 109 is connected with the at least one pushing head 108, and the rotary driving piece 109 is used for driving the at least one pushing head 108 to rotate;

the feeding frame 112 is arranged corresponding to the device body 101, and a sliding rail 111 is arranged on the feeding frame 112;

the tube unloading mechanism 110 is movably arranged on the slide rail 111, and the tube unloading mechanism 110 is used for loading and unloading the unreeling tube core.

The automatic unwinding device that is used for new energy automobile mica plate to process that this embodiment provided, it includes: the device comprises a device body 101, a rotary driving member 109 and a pipe unloading mechanism 110, wherein at least two pushing heads 108 are arranged on the device body 101, at least one pushing head 108 in the two pushing heads 108 can move relative to the other pushing head 108, the pushing heads 108 can rotate, the rotary driving member 109 can drive any one of the two pushing heads 108 to rotate, in the unreeling process, the two pushing heads 108 respectively push against two ends of an unreeling pipe core of a mica paper roll, the pushing heads 108 are driven to rotate by the rotary driving member 109 so as to drive the mica paper roll to rotate to realize automatic unreeling, after the mica paper roll is completely unreeled, the pipe unloading mechanism 110 moves to a set position along a slide rail 111, the pushing heads 108 move to increase the distance between the two pushing heads, the unreeling pipe core is separated from the pushing heads 108 and transferred to the pipe unloading mechanism 110, the pipe unloading mechanism 110 moves to load and unload the unreeling pipe core to and unload the pipe core to a working area again, then, a new mica paper roll is loaded and unloaded to a set position, and the jacking head 108 jacks and presses the unreeling pipe core again to unreel the mica paper roll.

The rotary driving member 109 in this embodiment may adopt a motor, the motor-driven transmission structure is connected to the pushing head 108, and the pushing head 108 is driven to rotate by the rotation of the motor, and further, the pushing head 108 in this embodiment is a conical structure, and the outer surface thereof is a conical surface, which can be more conveniently matched with the end of the unwinding tube core.

Device body 101 in this embodiment includes base portion 114, be provided with ledge 115 respectively at base portion 114's upper surface and lie in both sides, this ledge 115 protrudes base portion 114's upper surface, for wearing to establish space 104 between two ledges 115, be provided with work aircraft nose 105 on the ledge 115, be provided with telescopic link 106 on the work aircraft nose 105, fixed mounting has mounting panel 107 on the telescopic link 106, top pressure head 108 rotates through the pivot and installs on mounting panel 107, telescopic link 106 can be for work aircraft nose 105 telescopic movement, in addition, can also set up flexible drive part on the device body 101, flexible drive part is used for driving telescopic link 106 telescopic movement, the transmission structure can set up the inside at work aircraft nose 105.

In a further implementation manner of this embodiment, the tube discharging mechanism 110 includes a tube discharging rack 1101, a movable swing arm 1110, and a swing link driving element, wherein the tube discharging rack 1101 is movably mounted on the sliding rail 111 so that the tube discharging rack 1101 can move toward the apparatus body 101 and toward the apparatus body 101, the movable swing arm 1110 is hinged to the tube discharging rack 1101, the swing link driving element is connected to the movable swing arm 1110 for driving the movable swing arm 1110 to swing, and the movable swing arm 1110 has a receiving space 1106 for receiving an unreeled tube core.

In this embodiment, the unreeling tube core can be taken and placed by swinging the movable swing arm 1110, specifically, the movable swing arm 1110 can stretch into the lower portion of the unreeling tube core and the accommodating space 1106 is aligned with the unreeling tube core, the movable swing arm 1110 swings upwards to place the unreeling tube core into the accommodating space 1106, and the unreeling tube core can be taken and placed conveniently by using the movable swing arm 1110.

In a further implementation manner of this embodiment, the tube discharging mechanism 110 further includes a sliding driving member 1102, and the sliding driving member 1102 is connected to the tube discharging bracket 1101 for driving the tube discharging bracket 1101 to move along the slide rail 111.

The sliding driving member 1102 in this embodiment can facilitate the movement of the pipe discharging bracket 1101, so as to drive the whole pipe discharging mechanism 110 to move.

In a further implementation manner of this embodiment, a plurality of support brackets 103 are disposed on the apparatus body 101 along the length direction thereof, and the support brackets 103 are used for supporting and unwinding the die.

The supporting bracket 103 in this embodiment is used for placing the unreeling pipe core, and can place a plurality of mica paper rolls simultaneously, so that the mica paper rolls can be automatically taken and placed conveniently.

In a further embodiment of this embodiment, the device body 101 is provided with a sliding slot 102 along the length direction thereof, and the supporting bracket 103 is movably disposed in the sliding slot 102.

Support 103 activity in this embodiment sets up and can conveniently place the mica paper roll on support 103 in spout 102, and specifically, the side of support 103 in this embodiment is provided with gyro wheel 113, and the border contact of gyro wheel 113 and spout 102.

In addition, the supporting bracket 103 in this embodiment is provided with an opening for placing the unreeling pipe core, and the supporting bracket 103 in this embodiment is also provided on the protruding frame 115, so that the movable swing arm 1110 can extend into the penetrating space 104 to reach the lower side of the unreeling pipe core.

In a further implementation manner of this embodiment, the swing link driving element includes a first driving cylinder 1104 and a second driving cylinder 1108, the accommodating space 1106 is disposed at a position close to the front end of the movable swing arm 1110, the piston end of the first driving cylinder 1104 is connected to the middle portion of the movable swing arm 1110, and the piston end of the second driving cylinder 1108 is connected to the front end of the movable swing arm 1110.

The mica paper roll of the present embodiment is generally heavier, the piston end of the first driving cylinder 1104 is connected to the middle portion of the movable swing arm 1110, and the piston end of the second driving cylinder 1108 is connected to the front end of the movable swing arm 1110 to provide a larger torque for loading and unloading the mica paper roll.

In a further implementation manner of the present embodiment, the pipe unloading mechanism 110 further includes a first mounting shaft 1111, a second mounting shaft 1112, and a third mounting shaft 1114, the number of the movable swing arms 1110 is at least two, the rear end of the movable swing arms 1110 is connected to the first mounting shaft 1111, the middle portion of the movable swing arms 1110 is connected to the second mounting shaft 1112, the front end of the movable swing arms 1110 is connected to the front end of the third mounting shaft 1113, the first mounting shaft is rotatably mounted on the pipe unloading bracket 1101, the cylinder body of the first driving cylinder 1104 is hinged to the pipe unloading bracket 1101, the piston end of the first driving cylinder 1104 is hinged to the second mounting shaft, the cylinder body of the second driving cylinder 1108 is hinged to the pipe unloading bracket 1101, and the piston end of the second driving cylinder 1108 is hinged to the third mounting shaft.

The first mounting shaft 1111, the second mounting shaft 1112, and the third mounting shaft 1114 in this embodiment make the connection strength of the movable swing arm 1110 higher.

The tube discharging mechanism 110 in this embodiment further includes a connecting rod 1113, and two ends of the connecting rod 1113 are connected to the movable swing arm 1110.

In a further implementation manner of this embodiment, the movable swing arm 1110 includes a straight arm section 1103, a slant arm section 1105 extending obliquely downward at a front end of the straight arm section 1103, an arc arm 1107 extending obliquely upward at a front end of the slant arm section 1105, and a receiving space 1106 for receiving the unreeling bobbin is between the slant arm section 1105 and the arc arm 1107.

The structure of the movable swing arm 1110 in this embodiment can facilitate the operation to load and unload the unreeling pipe core.

In a further implementation of this embodiment, the second driving cylinder 1108 is disposed diagonally.

The diagonal arrangement of the second drive cylinder 1108 in this embodiment can provide a greater torque.

In a further implementation of this embodiment, the slide driver 1102 is a driving cylinder disposed along the length of the slide rail 111.

The automatic unwinding device in this embodiment further includes a sensing unit (not shown in the figure), and the sensing unit is used for sensing the winding head and the winding tail.

Specifically, when the automatic unwinding device in this embodiment is in operation, when the sensing unit identifies the winding head, the pushing head 108 is started to rotate to realize automatic unwinding, when the sensing unit identifies the winding tail, the pushing head 108 stops rotating, the tube discharging mechanism 110 moves to the position of the working head 105 and below the unwinding tube core, the pushing head 108 retracts, the movable swing arm 1110 swings upward to take off the unwound tube core after unwinding, then the tube discharging mechanism 110 moves to the position of the empty support bracket 103 to align the unwound tube core with the opening of the support bracket 103, the movable swing arm 1110 swings downward to place the unwound tube core on the support bracket 103, after discharging is completed, the tube discharging mechanism 110 moves to the position of the support bracket 103 loaded with the mica paper roll, and the movable swing arm 1110 extends deep below the mica paper roll, the movable swing arm 1110 moves upward to load the mica paper roll on the movable swing arm 1110, further moving to the position of the working head 105, simultaneously, the movable swing arm 1110 further moves upwards to align the unwinding tube core of the mica paper roll with the pressing head 108, the pressing head 108 extends out to press against the two ends of the unwinding tube core of the mica paper roll, and the movable swing arm 1110 moves downwards to separate from the unwinding tube core of the mica paper roll and moves to a position outside the working area.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (10)

1. A mica plate production system for a new energy automobile, comprising:

the plate stacking mechanism comprises a first mounting frame, a slide rail is arranged on the first mounting frame along the length direction of the first mounting frame, a sliding support is movably mounted on the slide rail, a plate stacking platform is further arranged on the first mounting frame, the top surface of the plate stacking platform is a placing plane for placing mica plates, clamping mechanisms are arranged on two sides of the sliding support, and the clamping mechanisms can move to the position above the placing plane along with the sliding support;

the paper cutting mechanism is arranged at the first end of the plate stacking mechanism and is used for cutting mica paper;

and the placing platform is arranged at the second end of the plate stacking mechanism and is used for placing the glass fiber cloth.

2. The mica plate production system for the new energy automobile as claimed in claim 1, wherein the paper cutting mechanism comprises a second mounting frame, a conveying belt, a conveying mechanism and a paper cutting machine head are arranged on the second mounting frame, the conveying belt is used for contacting with the mica paper, a rotating roller is arranged on the second mounting frame, the conveying belt is driven by the rotating roller, the conveying mechanism is used for driving the mica paper to move, the paper cutting machine head at least comprises a paper cutting tool, a transverse sliding rail and a tool driving mechanism, the transverse sliding rail is arranged along the width direction of the second mounting frame, the paper cutting tool is movably arranged on the transverse sliding rail, and the tool driving mechanism is connected with the paper cutting tool and used for driving the paper cutting tool to move along the transverse sliding rail.

3. The mica board production system for the new energy automobile as claimed in claim 1, wherein the placement platform comprises a third installation frame, and a fiberglass cloth platform is arranged on the third installation frame.

4. The mica plate production system for the new energy automobile as recited in claim 3, wherein a fiberglass cloth conveying mechanism is arranged at one end of the third installation frame, which is close to the plate stacking mechanism.

5. The mica plate production system for the new energy automobile as claimed in claim 4, wherein a blowing mechanism is further arranged on the third mounting frame.

6. The mica plate production system for the new energy automobile as claimed in claim 5, wherein the fiberglass cloth conveying mechanism comprises a drive roller, the drive roller is connected with a driving motor, the drive roller is located above the fiberglass cloth platform, the blowing mechanism is arranged above the drive roller, and a blowing port of the blowing mechanism faces the drive roller.

7. The mica plate production system for the new energy automobile as claimed in claim 6, wherein a toothed part is arranged on the driving roller, the toothed part is made of rubber, and teeth are arranged on the surface of the toothed part.

8. The mica plate production system for the new energy automobile as recited in claim 6, wherein a driven roller is arranged below the driving roller, the driven roller is close to the plate stacking mechanism relative to the driving roller, and the driven roller is rotatably mounted on the third mounting frame.

9. The mica plate production system for the new energy automobile as recited in claim 8, wherein a rubber layer is provided on a surface of the driven roller.

10. The mica plate production system for the new energy automobile according to any one of claims 3 to 9, wherein a vertical rail is vertically arranged on the first installation frame, the fiberglass cloth platform is movably arranged on the vertical rail, and the fiberglass cloth platform is connected with a vertical driving mechanism.

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