CN210489767U

CN210489767U - Die cutting and laminating integrated equipment

Info

Publication number: CN210489767U
Application number: CN201921300969.5U
Authority: CN
Inventors: 鲁树立; 张进; 刘克亚; 罗杨青; 王庆祎
Original assignee: SHENZHEN GREENSUN TECHNOLOGY CO LTD
Current assignee: Shenzhen Greensheng Technology Co ltd
Priority date: 2019-08-06
Filing date: 2019-08-06
Publication date: 2020-05-08
Anticipated expiration: 2029-08-06

Abstract

The utility model discloses a die-cutting and lamination integrated device, relating to the technical field of battery production equipment; the device comprises a pole piece die cutting mechanism, a pole piece conveying mechanism, a positive pole piece feeding mechanism, a negative pole piece feeding mechanism, a diaphragm unreeling mechanism and a double lamination table mechanism; the positive plate feeding mechanism and the negative plate feeding mechanism are respectively arranged at two sides of the double-lamination-table mechanism, the pole piece conveying mechanism is arranged between the pole piece die-cutting mechanism and the positive plate feeding mechanism and between the pole piece die-cutting mechanism and the negative plate feeding mechanism, and the diaphragm unwinding mechanism is positioned above the double-lamination-table mechanism; the double-lamination-table mechanism comprises a rotating shaft, a rotating arm, a central rotating shaft, a first lamination table and a second lamination table; the utility model has the advantages that: the equipment can realize die cutting and lamination of the pole piece, solves the problems of low automation degree and low production efficiency of the equipment in the prior art, can realize continuous lamination operation, and improves the lamination efficiency.

Description

Die cutting and laminating integrated equipment

Technical Field

The utility model relates to a battery production facility technical field, more specifically the utility model relates to a cross cutting lamination equipment.

Background

The lithium ion battery is a new generation of green high-energy battery with excellent performance, and has become one of the key points of high and new technology development. The lithium ion battery has the following characteristics: high voltage, high capacity, low consumption, no memory effect, no public hazard, small volume, small internal resistance, less self-discharge and more cycle times. Because of the above characteristics, lithium ion batteries have been applied to various civil and military fields such as mobile phones, notebook computers, video cameras, digital cameras, and the like.

The battery core of the lithium ion battery is generally of a laminated type, namely, a positive plate, a diaphragm and a negative plate are arranged in a laminated mode, when lamination is carried out, a Z-shaped integrated battery core laminating machine is generally adopted, namely, the positive plate and the negative plate are respectively transported to a positive lamination station and a negative lamination station from a material box through positive and negative plate suckers, the diaphragm is pulled to the lower side of the positive plate, the positive plate is pressed on one side face of the diaphragm, the diaphragm is pulled to the lower side of the negative plate, the negative plate is pressed on the other side face of the diaphragm and sequentially reciprocates until the positive plate and the negative plate with preset layers are respectively laminated on the two sides of the diaphragm, and after lamination is completed, the pole pieces are clamped through a winding mechanical arm and continuously rotate to enable the diaphragm to be wound.

However, the existing equipment generally has the defect of single function, one processing equipment generally can only realize one processing function, and the problems of low automation degree, large occupied space, high production cost and waste of human resources exist. In addition, in the conventional lamination equipment, the lamination table can continue to perform lamination after the blanking mechanism finishes actions such as diaphragm cutting, clamping and withdrawing, so that the lamination table is in an empty state after a first battery cell is formed and before lamination with a second battery cell is started, the working time is wasted, the lamination efficiency is not high, and the production speed of the battery cell is limited.

SUMMERY OF THE UTILITY MODEL

In order to overcome the not enough of prior art, the utility model provides an integrative equipment of cross cutting lamination, this equipment can realize the cross cutting and the lamination of pole piece, and the equipment degree of automation who solves among the prior art is low, problem that production efficiency is low to can realize continuous lamination operation, improve lamination efficiency.

The utility model provides a technical scheme that its technical problem adopted is: the improvement of a die-cutting lamination integrated device is that: the device comprises a pole piece die cutting mechanism, a pole piece conveying mechanism, a positive pole piece feeding mechanism, a negative pole piece feeding mechanism, a diaphragm unreeling mechanism and a double lamination table mechanism;

the positive plate feeding mechanism and the negative plate feeding mechanism are respectively arranged at two sides of the double-lamination-table mechanism, the pole piece conveying mechanism is arranged between the pole piece die-cutting mechanism and the positive plate feeding mechanism and between the pole piece die-cutting mechanism and the negative plate feeding mechanism, and the diaphragm unwinding mechanism is positioned above the double-lamination-table mechanism;

the double-lamination-table mechanism comprises a rotating shaft, rotating arms, a central rotating shaft, a first lamination table and a second lamination table, wherein two ends of the rotating shaft are fixedly connected with the middle part of one rotating arm respectively, and the first lamination table and the second lamination table are arranged between the two rotating arms and are positioned on two sides of the rotating shaft respectively; one central rotating shaft penetrates through the first lamination table, two ends of the central rotating shaft are respectively and rotatably connected with one end of each of the two rotating arms, the other central rotating shaft penetrates through the second lamination table, and two ends of the central rotating shaft are respectively and rotatably connected with the other ends of the two rotating arms; the first lamination platform and the second lamination platform are used for achieving stacking of pole pieces.

In the above structure, the first lamination stage and the second lamination stage have the same structure; the first lamination table comprises a lamination seat body and a pressing component, the central rotating shaft penetrates through the center of the lamination seat body, the pressing components are arranged on the opposite side walls of the lamination seat body, and each pressing component comprises a pressing driving device, a rotating shaft, a rotating cam, a translation sliding block and a pressing plate;

two rotating cams are fixedly arranged on the rotating shaft, each rotating cam is provided with an inclined guide ring, and the guide rings on the two rotating cams are symmetrical along the radial center line of the rotating shaft; two translation sliding blocks are slidably mounted on the opposite side walls of the lamination seat body, a limit stop is fixedly mounted on each translation sliding block, and a guide ring of the rotating cam is clamped in a limit groove of the limit stop;

the pressing plate is 7-shaped, one end of the pressing plate is fixedly arranged on the translation sliding block, and the other end of the pressing plate extends to the upper part of the lamination seat body; the tabletting driving device is arranged on the side wall of the lamination seat body and is used for driving the rotating shaft to rotate.

In the above structure, the first lamination table further includes a lifting assembly, the lifting assembly includes a lifting slide plate and a lifting driving device, the lifting slide plate is disposed on the opposite side wall of the lamination base, and the lifting driving device is configured to drive the lifting slide plate to slide up and down on the side wall of the lamination base;

the rotating shaft and the pressing sheet driving device are both arranged on the lifting sliding plate, a translation sliding rail is fixedly arranged on the lifting sliding block, and the translation sliding block is slidably arranged on the translation sliding rail.

In the above structure, the lifting driving device includes a lifting motor, a transmission belt, a lifting screw rod, a lifting block and a lifting slide rail;

the lifting motor is fixed on the inner wall of the lamination seat body, two ends of the lifting screw rod are rotatably installed on the inner wall of the lamination seat body, the lifting screw rod is matched with the lifting block, and the transmission belt is sleeved between an output wheel of the lifting motor and a rotating wheel positioned at one end of the lifting screw rod; the lifting block is fixedly connected with the lifting slide block, the lifting slide rail is arranged on the outer wall of the lamination seat body, and the lifting slide plate is slidably arranged on the lifting slide rail;

the pressing sheet driving device comprises a driving motor and a pressing sheet belt, the driving motor is fixed on the lifting sliding plate, a driving wheel is installed at the top end of a motor shaft of the driving motor, a driven wheel is installed at the top end of the rotating shaft, and the pressing sheet belt is sleeved on the driving wheel and the driven wheel.

In the structure, a lamination frame is fixedly arranged above the lamination seat body, the lamination seat body comprises a top plate and two fixed side plates which are oppositely arranged, the top plate is fixedly arranged at the tops of the two fixed side plates, and the lamination frame is arranged on the upper surface of the top plate;

the lamination device is characterized in that a lamination clamping jaw is installed on the lamination plate, one end of the lamination clamping jaw is fixed to the top end of the lamination plate, and the other end of the lamination clamping jaw extends to the upper portion of the lamination frame.

In the structure, the structure of the positive plate feeding mechanism is the same as that of the negative plate feeding mechanism, wherein the positive plate feeding mechanism comprises a working platform, a feeding assembly, a tray transverse moving assembly and a material returning assembly;

the feeding assembly comprises a feeding conveyor belt and two first side vertical plates which are fixed on the working platform in parallel, the feeding conveyor belt is arranged on the side surface of each first side vertical plate, and the feeding conveyor belt is used for conveying a feeding disc above the first side vertical plates;

the feed back assembly comprises a feed back conveyor belt and two second side vertical plates which are fixed on the working platform in parallel, the second side vertical plates are positioned on one sides of the first side vertical plates and are parallel to the first side vertical plates, the feed back conveyor belt is installed on the side surfaces of the second side vertical plates, and the feed back conveyor belt is used for conveying the feeding disc above the second side vertical plates;

the charging tray transverse moving assembly comprises two parallel longitudinal conveying belts, the longitudinal conveying belts are perpendicular to the feeding conveying belts, notches used for containing the longitudinal conveying belts are arranged on the first side vertical plate and the second side vertical plate, the feeding conveying belts are also arranged on the first side vertical plate between the two longitudinal conveying belts, and the feeding conveying belts are also arranged on the second side vertical plate between the two longitudinal conveying belts.

In the structure, a first transition wheel is arranged below the gap of the first side vertical plate, a first supporting wheel is arranged on the first side vertical plate between the two longitudinal conveying belts, and the feeding conveying belt bypasses from the lower part of the first transition wheel and bypasses from the upper part of the first supporting wheel;

and a second transition wheel is arranged below the gap of the second side vertical plate, a second supporting wheel is arranged on the second side vertical plate between the two longitudinal conveying belts, and the feed back conveying belt bypasses from the lower part of the second transition wheel and bypasses from the upper part of the second supporting wheel.

In the structure, the pole piece die-cutting mechanism comprises a fixed box body, and a pole piece feeding assembly, a forming die-cutting assembly, a pole lug die-cutting assembly and a pole piece feeding assembly which are sequentially arranged on the side wall of the fixed box body;

the pole piece feeding assembly is used for providing raw materials to be subjected to die cutting for the first die cutting assembly, the forming die cutting assembly is used for die cutting the raw materials into pole pieces, and the pole lug die cutting assembly is used for forming a pole lug on the pole piece.

In the structure, the tab die-cutting assembly comprises a die-cutting support frame, a first die-cutting assembly, a second die-cutting assembly and a position adjusting assembly;

the first die cutting assembly and the second die cutting assembly are arranged on the die cutting support frame side by side, and the first die cutting assembly and the second die cutting assembly are identical in structure, wherein the first die cutting assembly comprises a die cutting upper seat, a die cutting lower seat and a die cutting driving device for driving the die cutting upper seat to realize lifting movement, and the die cutting driving device is fixed on the die cutting support frame;

the position adjusting assembly comprises a lower bottom plate, a first adjusting wheel, a translation sliding rail, a second adjusting wheel, a first screw and a second screw;

the translational slide rail is fixed on the die cutting support frame, the die cutting lower seat of the first die cutting assembly and the die cutting lower seat of the second die cutting assembly are respectively fixed on a lower bottom plate, the two lower bottom plates are arranged on the translational slide rail in a sliding mode side by side, and the lower surfaces of the two lower bottom plates are respectively and fixedly provided with a screw nut; the first adjusting wheel is connected with a first screw rod, the second adjusting wheel is connected with a second screw rod, and the first screw rod is arranged below one of the lower base plates and penetrates through a screw nut on the lower base plate; the second screw is arranged below the other lower bottom plate and penetrates through the screw nut on the lower bottom plate.

In the structure, the die cutting driving device comprises a first die cutting motor, a motor base body, a lifting sliding plate, a lifting sliding rail, a lifting screw rod and a lifting screw rod nut; the first die-cutting motor is fixed on the motor seat body, and the motor seat body is fixedly connected with the die-cutting support frame; the lifting slide rail is arranged on the side wall of the motor seat body along the vertical direction, and the lifting slide plate is arranged on the lifting slide rail in a sliding manner; an output shaft of the first die cutting motor is connected with a lifting screw rod, a lifting screw rod nut is arranged on the lifting screw rod and fixed on the back of a lifting sliding plate, and the lifting sliding plate is fixedly connected with a die cutting upper seat;

the die cutting driving device also comprises a vertical connecting plate; the bottom of lift slide is provided with and is horizontally transverse connection board, two gyro wheels are installed along vertical direction at the top of vertical connecting plate, transverse connection board card go into between two gyro wheels, the bottom and the cross cutting seat of honour fixed connection of vertical connecting plate.

The utility model has the advantages that: the utility model discloses a die-cutting lamination integrated equipment, the work of a plurality of equipment in the past just can be accomplished in a equipment, and degree of automation is high, can greatly promote the work efficiency of equipment, reduces intensity of labour and cost of labor; meanwhile, due to the structural design of the double lamination table mechanism, in the lamination operation process, the rotary switching of the first lamination table and the second lamination table can be realized, and the preparation work of clamping, pressing and the like of the first-layer diaphragm of the next battery cell is completed in the blanking process of the first battery cell, so that the blanking time is greatly saved, the lamination efficiency of equipment is improved, and the production efficiency of products is improved.

Drawings

Fig. 1 is the utility model discloses a structural schematic of the integrative equipment of cross cutting lamination.

Fig. 2 is the utility model discloses a side structure schematic diagram of positive plate feed mechanism, lower pole piece feed mechanism and two lamination platform mechanisms of the integrative equipment of cross cutting lamination.

Fig. 3 is the utility model discloses a three-dimensional structure schematic diagram of positive plate feed mechanism, lower pole piece feed mechanism and two lamination platform mechanisms of the integrative equipment of cross cutting lamination.

Fig. 4 is the utility model discloses a three-dimensional structure schematic diagram of two lamination platform mechanisms of integrative equipment of cross cutting lamination.

Fig. 5 is a schematic structural diagram of a first lamination stage of the dual lamination stage mechanism of the present invention.

Fig. 6 is the utility model discloses a structure schematic diagram of positive plate feed mechanism of integrative equipment of cross cutting lamination.

Fig. 7 is the utility model discloses a structural schematic diagram of pole piece die-cutting mechanism of integrative equipment of cross cutting lamination.

Fig. 8 is the structural schematic diagram of the tab die-cutting mechanism of the pole piece die-cutting mechanism of the present invention.

Fig. 9 is a schematic structural diagram of the dust removing structure of the pole piece die cutting mechanism of the present invention.

Detailed Description

The present invention will be further explained with reference to the drawings and examples.

The conception, the specific structure, and the technical effects produced by the present invention will be clearly and completely described below in conjunction with the embodiments and the accompanying drawings to fully understand the objects, the features, and the effects of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and other embodiments obtained by those skilled in the art without inventive labor based on the embodiments of the present invention all belong to the protection scope of the present invention. In addition, all the connection/connection relations referred to in the patent do not mean that the components are directly connected, but mean that a better connection structure can be formed by adding or reducing connection auxiliary components according to specific implementation conditions. The utility model discloses each technical feature in the creation can the interactive combination under the prerequisite that does not contradict conflict each other.

Referring to fig. 1, 2 and 3, the utility model discloses a die-cutting lamination integrated device, which realizes the die-cutting and lamination process of pole pieces to produce electric cores; specifically, the die-cutting and laminating integrated equipment comprises a pole piece die-cutting mechanism 100, a pole piece conveying mechanism 200, a positive pole piece feeding mechanism 40, a negative pole piece feeding mechanism 10, a diaphragm unreeling mechanism 20 and a double-lamination-table mechanism 30, wherein the positive pole piece feeding mechanism 40 and the negative pole piece feeding mechanism 10 are respectively arranged on two sides of the double-lamination-table mechanism 30, the pole piece conveying mechanism 200 is arranged between the pole piece die-cutting mechanism 100 and the positive pole piece feeding mechanism 40 and between the pole piece die-cutting mechanism 100 and the negative pole piece feeding mechanism 10, and the diaphragm unreeling mechanism 20 is positioned above the double-lamination-table mechanism 30; the pole piece die-cutting mechanisms 100 positioned on two sides of the equipment are used for die-cutting pole pieces, cutting out pole pieces meeting requirements, transmitting the pole pieces under the action of the pole piece conveying mechanism 200, and conveying the pole pieces to the positive pole piece feeding mechanism 40 or the negative pole piece feeding mechanism 10; the membrane unreeling mechanism 20 is located above the double lamination table mechanism 30 and is used for providing the membrane clamped between the positive plate and the negative plate for the double lamination table mechanism 30, and the lamination operation of the positive plate and the negative plate is realized through the double lamination table mechanism 30; therefore, the utility model discloses an integrative equipment of cross cutting lamination just can accomplish the work of a plurality of equipment in the past in an equipment, and degree of automation is high, can greatly lifting means's work efficiency, reduces intensity of labour and cost of labor.

As shown in fig. 3, in the present embodiment, two sets of double lamination table mechanisms 30 are arranged side by side on the same support frame, and the structures thereof are completely the same, and only the structure of one set of double lamination table mechanism is described in detail in the present embodiment. In addition, it should be noted that a plurality of material transferring mechanical arms 102 are further disposed on the platform supporting frame 101, and the material transferring mechanical arms 102 are used for transferring the positive electrode sheet and the negative electrode sheet, for example, transferring the positive electrode sheet conveyed by the positive electrode sheet feeding mechanism 40 to the double lamination table mechanism 30, and the structure of the material transferring mechanical arms 102 is common in the prior art, and the specific structure thereof is not explained in this embodiment.

For the double-lamination-table mechanism 30, as shown in fig. 4 and 5, the utility model provides a specific embodiment, the double-lamination-table mechanism 30 includes a rotating shaft 301, a rotating arm 302, a central rotating shaft 303, a first lamination table 304 and a second lamination table 305, two ends of the rotating shaft 301 are respectively rotatably installed at the top of a supporting seat 306, two ends of the rotating shaft 301 are respectively fixedly connected with the middle part of the rotating arm 302, the first lamination table 304 and the second lamination table 305 are both arranged between the two rotating arms 302 and are respectively located at two sides of the rotating shaft 301; a central rotating shaft 303 penetrates through the first lamination station 304, two ends of the central rotating shaft 303 are respectively and rotatably connected with one end of the two rotating arms 302, the other central rotating shaft 303 penetrates through the second lamination station 305, and two ends of the central rotating shaft 303 are respectively and rotatably connected with the other end of the two rotating arms 302; the first lamination station 304 and the second lamination station 305 are both used for realizing the lamination of the pole pieces.

Through the structure, the rotating shaft 301 can be driven to rotate under the driving of power, the rotating arm 302 is driven to rotate in the vertical direction, and the first lamination table 304 and the second lamination table 305 are both in rotating connection with the rotating arm 302 through the action of the central rotating shaft 303, so that the first lamination table 304 and the second lamination table 305 can both be kept in a horizontal high state when the rotating arm 302 rotates; during the lamination operation, the first lamination table 304 and the second lamination table 305 can be switched in a rotating manner, and the preparation work of clamping, compressing and the like of the first-layer diaphragm of the next electric core is completed in the first electric core blanking process, so that the blanking time is greatly saved, the lamination efficiency of equipment is improved, and the production efficiency of products is improved.

In the above embodiment, the first lamination table 304 and the second lamination table 305 are identical in structure, in this embodiment, only the structure of the first lamination table 304 is described in detail, the first lamination table 304 includes a lamination base 3041 and a sheet pressing assembly 3042, the central rotating shaft 303 passes through the center of the lamination base 3041, a lamination frame 3043 is fixedly installed above the lamination base 3041, the lamination base 3041 includes a top plate 3044 and two opposite fixed side plates 3045, the top plate 3044 is fixedly installed on the tops of the two fixed side plates 3045, and the lamination frame 3043 is installed on the upper surface of the top plate 3044.

Further, the opposite side walls of the lamination seat 3041 are respectively provided with a tablet assembly 3042, the tablet assembly 3042 includes a tablet driving device, a rotating shaft 3046, a rotating cam 3047, a translational slide block 3048 and a tablet pressing plate 3049; two rotating cams 3047 are fixedly mounted on the rotating shaft 3046, each rotating cam 3047 is provided with an inclined guide ring, and the guide rings on the two rotating cams 3047 are symmetrical along the radial center line of the rotating shaft 3046; two translation sliders 3048 are slidably mounted on the opposite side walls of the lamination seat 3041, a limit stop 3050 is fixedly mounted on each translation slider 3048, and a guide ring of the rotating cam 3047 is clamped in a limit groove of the limit stop 3050; the pressing sheet plate 3049 is in a shape of "7", one end of the pressing sheet plate 3049 is fixedly mounted on the translation slider 3048, and the other end of the pressing sheet plate 3049 extends above the lamination seat 3041; with such a structure, when the rotating shaft 3046 rotates, the limit baffle drives the translating slider 3048 to translate in the horizontal direction under the driving action of the rotating cam 3047, and since the two rotating cams 3047 have the same structure and the guide rings on the rotating cam 3047 are symmetrical along the radial center line of the rotating shaft 3046, the two limit sliders can move simultaneously in different directions to drive the sheet pressing plate 3049 to open and close. The tablet driving device is disposed on a sidewall of the lamination base 3041 and is used to drive the rotating shaft 3046 to rotate. A pressing plate clamping jaw 3051 is mounted on the pressing plate 3049, one end of the pressing plate clamping jaw 3051 is fixed to the top end of the pressing plate 3049, and the other end of the pressing plate clamping jaw 3051 extends to the upper side of the lamination frame 3043.

Further, the first lamination table 304 further includes a lifting assembly, the lifting assembly includes a lifting slide plate 3052 and a lifting driving device, the lifting slide plate 3052 is disposed on the opposite side wall of the lamination base 3041, and the lifting driving device is configured to drive the lifting slide plate 3052 to slide up and down on the side wall of the lamination base 3041; the rotating shaft 3046 and the tablet pressing driving device are both mounted on a lifting sliding plate 3052, a translation sliding rail 3053 is further fixedly mounted on the lifting sliding block, and the translation sliding block 3048 is slidably mounted on the translation sliding rail 3053. In this embodiment, as shown in fig. 2, the lifting driving device includes a lifting motor 3054, a transmission belt 3055, a lifting screw 3056, a lifting block 3057 and a lifting slide 3058; the lifting motor 3054 is fixed on the inner wall of the lamination base 3041, two ends of the lifting screw 3056 are rotatably mounted on the inner wall of the lamination base 3041, the lifting screw 3056 is matched with the lifting block 3057, and the transmission belt 3055 is sleeved between an output wheel of the lifting motor 3054 and a rotating wheel positioned at one end of the lifting screw 3056; the lifting block 3057 is fixedly connected with the lifting slider, the lifting slide rail 3058 is mounted on the outer wall of the lamination base 3041, and the lifting slide plate 3052 is slidably mounted on the lifting slide rail 3058.

In the above embodiment, the tablet pressing driving device includes a driving motor (not labeled in the figure) and a tablet pressing belt 3059, the driving motor is fixed on the lifting slide plate 3052, a driving wheel is installed at a top end of a motor shaft of the driving motor, a driven wheel is installed at a top end of the rotating shaft 3046, and the tablet pressing belt 3059 is sleeved on the driving wheel and the driven wheel.

Through the structure, the lifting assembly is arranged inside the lamination base 3041, a hidden structure design is realized, the lifting assembly is prevented from additionally occupying the volume of the first lamination table 304, and the whole structure is more compact and small; in the lamination process, the lifting assembly can drive the lifting sliding plate 3052 to reciprocate in the vertical direction, meanwhile, under the driving of the rotating force of the rotating shaft 3046, the two opposite pressing clamping jaws 3051 can simultaneously realize the opening or closing action, the pressing clamping jaws 3051 can realize the pressing and loosening of the diaphragm according to the control, and the lamination operation is realized, and the first lamination table 304 with the structure is compact and reasonable in structure. After the lamination is realized on the first lamination platform 304 to form the battery core, the first lamination platform 304 is rotated, when the diaphragm and the blanking are cut off, the actions of clamping, compressing and the like of the diaphragm on the second lamination platform 305 are completed, the blanking of the battery core on the first lamination platform 304 is not required to be waited, so that the time for cutting off and blanking the diaphragm in each lamination period is shortened, the lamination efficiency is improved, meanwhile, the lamination operation is realized on the first lamination platform 304 and the second lamination platform 305 one by one, the condition of double laminations on the lamination platform can be prevented, the damage to the battery core is avoided, and the yield of products is improved.

As shown in fig. 6, for the positive plate feeding mechanism 40 and the negative plate feeding mechanism 10, the present invention provides a specific embodiment, since the structures of the positive plate feeding mechanism 40 and the negative plate feeding mechanism 10 are completely the same, the structure of the positive plate feeding mechanism 40 is only used for detailed description in this embodiment.

The positive plate feeding mechanism 40 comprises a working platform 401, a feeding assembly, a tray transverse moving assembly and a material returning assembly; the feeding assembly comprises a feeding conveyor belt 402 and two first side vertical plates 403 which are fixed on the working platform 401 in parallel, the feeding conveyor belt 402 is installed on the side surfaces of the first side vertical plates 403, and the feeding conveyor belt 402 is used for conveying a feeding tray 404 above the first side vertical plates 403; the feeding back assembly comprises a feeding back conveyor belt 405 and two second side vertical plates 406 which are fixed on the working platform 401 in parallel, the second side vertical plates 406 are positioned on one side of the first side vertical plates 403 and are parallel to the first side vertical plates 403, the feeding back conveyor belt 405 is installed on the side surfaces of the second side vertical plates 406, and the feeding back conveyor belt 405 is used for conveying the feeding tray 404 above the second side vertical plates 406; the tray transverse moving assembly comprises two parallel longitudinal conveyor belts 407, the longitudinal conveyor belts 407 are perpendicular to the feeding conveyor belt 402, the first side vertical plate 403 and the second side vertical plate 406 are both provided with notches for accommodating the longitudinal conveyor belts 407, the feeding conveyor belt 402 is also arranged on the first side vertical plate 403 between the two longitudinal conveyor belts 407, and the return conveyor belt 405 is also arranged on the second side vertical plate 406 between the two longitudinal conveyor belts 407. In this embodiment, a first transition wheel (not labeled in the figure) is arranged below the gap of the first side vertical plate 403, a first support wheel 408 is arranged on the first side vertical plate 403 between the two longitudinal conveyor belts 407, and the feeding conveyor belt 402 bypasses below the first transition wheel and bypasses above the first support wheel 408; a second transition wheel is arranged below the gap of the second side vertical plate 406, a second supporting wheel 409 is arranged on the second side vertical plate 406 between the two longitudinal conveyor belts 407, and the feed back conveyor belt 405 bypasses from the lower part of the second transition wheel and bypasses from the upper part of the second supporting wheel 409.

Through the above structure, the feeding tray 404 is conveyed above the two first side vertical plates 403 by the feeding conveyor 402, the feeding conveyor 402 is wound on a plurality of rollers, and the rotation is realized through the rotation of the motor, which belongs to the category of the prior art, and the detailed description is omitted in this embodiment. When the feeding disc 404 is conveyed to the tail end of the feeding conveyor belt 402, the feeding disc 404 is located on the longitudinal conveyor belts 407, pole pieces are fed at the position, after feeding is completed, the empty feeding disc moves to the return conveyor belts 405 under the driving of the feeding conveyor belts 402, and is driven by the return conveyor belts 405 to discharge the empty feeding disc. The utility model discloses a pole piece feed mechanism can realize the automatic feeding of pole piece and the automatic recovery of material frame, improves material loading efficiency, and degree of automation is high to low in cost.

In the structure, the feeding assembly further includes a feeding baffle 410, and the feeding baffle 410 is parallel to the first side vertical plates 403 and is located at the outer sides of the two first side vertical plates 403; the feed back assembly further comprises a feed back baffle 411, and the feed back baffle 411 is parallel to the second side vertical plates 406 and is positioned at the outer sides of the two second side vertical plates 406; the tray transverse moving assembly further comprises a longitudinal baffle 412, and the longitudinal baffle 412 is perpendicular to the feeding baffle 410 and is positioned at the tail end of the feeding conveyor belt 402; in addition, the front end of the feeding baffle 410 is provided with an inclined guide piece 413, and an inlet of the feeding tray 404 is formed between the two guide pieces 413. The position of the feeding tray 404 is limited by the action of the feeding baffle plate 410, the return baffle plate 411 and the longitudinal baffle plate 412, so that the position of the feeding tray 404 is prevented from deviating; due to the existence of the guide piece 413, the feeding tray 404 is convenient to move from the inlet to the feeding conveyor 402, and the situation that the feeding tray 404 is jammed in the transmission process is avoided. In addition, the feeding baffle plate 410, the return baffle plate 411 and the longitudinal baffle plate 412 are all fixed at the top end of a supporting column 416, and the supporting column 416 is fixed on the working platform 401.

In a preferred embodiment, as shown in fig. 6, the tray traversing assembly further comprises a longitudinal power shaft 414, a longitudinal driven shaft (not labeled), a longitudinal power belt 415 and a power motor (not labeled); the longitudinal conveyor belt 407 is sleeved on the longitudinal power shaft 414 and the longitudinal driven shaft, a belt pulley is installed at one end of the longitudinal power shaft 414, the power motor is located below the longitudinal conveyor belt 407, an output shaft of the power motor is provided with an output wheel, and the longitudinal power belt 415 is sleeved on the output wheel and the belt pulley.

In the above embodiment, a pinch roll mechanism and a diaphragm cutting mechanism are further disposed below the diaphragm unwinding mechanism 20, wherein the pinch roll mechanism is configured to send the diaphragm to a specified position after the diaphragm is gripped, and the diaphragm cutting mechanism is configured to cut the diaphragm; since the structures of the pinch roller mechanism and the diaphragm cutting mechanism are common in the prior art, detailed description is omitted in this embodiment.

As shown in fig. 7, for the pole piece die cutting mechanism 100, the present invention provides a specific embodiment, the pole piece die cutting mechanism 100 includes a fixed box 1001, and a pole piece feeding assembly 1002, a forming die cutting assembly 1003, a pole ear die cutting assembly 70 and a pole piece feeding assembly 1004 sequentially disposed on the sidewall of the fixed box 1001; the pole piece feeding assembly 1002 is configured to provide a raw material to be die-cut to the first die-cutting assembly, the forming die-cutting assembly 1003 is configured to die-cut the raw material into a pole piece, the tab die-cutting assembly 70 is configured to form a tab on the pole piece, the pole piece feeding assembly 1004 is configured to convey the die-cut pole piece, and then convey the die-cut pole piece through the pole piece conveying mechanism 200, generally, the pole piece conveying mechanism 200 is configured to be matched with a manipulator by a conveyor belt, and detailed description is omitted in this embodiment.

As shown in fig. 8, for the tab die-cutting assembly 70, the utility model provides a specific embodiment, the tab on the pole piece is cut by the tab die-cutting assembly 70, specifically, the tab die-cutting assembly 70 includes a die-cutting support frame 701, a first die-cutting assembly 702, a second die-cutting assembly 703 and a position adjusting assembly; the first die-cutting assembly 702 and the second die-cutting assembly 703 are mounted on the die-cutting support frame 701 side by side, and in this embodiment, the die-cutting support frame includes a first horizontal plate 704, a second horizontal plate 705 and a vertical support plate 706; the first horizontal plate 704 is fixed at the top end of the vertical supporting plate 706, the second horizontal plate 705 is fixed at the bottom end of the vertical supporting plate 706, the first horizontal plate 704 and the second horizontal plate 705 are positioned at the same side of the vertical supporting plate 706, and the first die-cutting assembly 702 and the second die-cutting assembly 703 are fixed on the first horizontal plate 704 side by side; in this embodiment, the first die-cutting assembly 702 and the second die-cutting assembly 703 have the same structure, so the present embodiment only describes the structure of the first die-cutting assembly 702 in detail, and the first die-cutting assembly 702 includes an upper die-cutting seat 707, a lower die-cutting seat 708, and a die-cutting driving device for driving the upper die-cutting seat 707 to perform a lifting motion, and the die-cutting driving device is fixed on the first horizontal plate 704.

Further, in the above embodiment, the position adjusting assembly includes a lower base plate 709, a first adjusting wheel 710, a translational sliding rail 711, a second adjusting wheel 712, a first screw 713, and a second screw 714, the translational sliding rail 711 is fixed on the upper surface of the second horizontal plate 705, the die-cutting lower seat 708 of the first die-cutting assembly 702 and the die-cutting lower seat 708 of the second die-cutting assembly 703 are respectively fixed on the lower base plate 709, the two lower base plates 709 are arranged side by side and slidably disposed on the translational sliding rail 711, and screw nuts (not labeled in the drawing) are fixedly disposed on the lower surfaces of the two lower base plates 709; the first adjusting wheel 710 is connected with a first screw 713, the second adjusting wheel 712 is connected with a second screw 714, and the first screw 713 is arranged below one of the lower bottom plates 709 and penetrates through a screw nut on the lower bottom plate 709; the second screw 714 is disposed below the other lower base plate 709 and passes through a screw nut on the lower base plate 709.

Through the structure, when the first adjusting wheel 710 is rotated, the first screw 713 is driven to rotate, one of the lower base plates 709 is driven to slide on the translation sliding rail 711 through the matching of the first screw 713 and the screw nut, similarly, when the second adjusting wheel 712 is rotated, the other lower base plate 709 is driven to slide on the translation sliding rail 711, the distance between the die-cutting lower seat 708 of the first die-cutting assembly 702 and the die-cutting lower seat 708 of the second die-cutting assembly 703 is adjusted through rotating the first adjusting wheel 710 and the second adjusting wheel 712 in different directions, and the die-cutting of the pole pieces is realized between the two die-cutting upper seats and the die-cutting lower seat, so that the die-cutting of the pole pieces with different sizes is adapted, the applicability and the universality of the die-cutting equipment are improved, the manufacturing cost of the die-cutting equipment is reduced, and one machine with multiple purposes is realized.

As a preferred embodiment, as shown in fig. 8, for the die cutting driving device, the present invention provides a specific embodiment, the die cutting driving device includes a first die cutting motor 715, a motor base 716, a lifting slider 717, a lifting slide rail 718, a lifting screw (not labeled in the figure) and a lifting screw nut (not labeled in the figure); the first die cutting motor 715 is fixed on the motor base 716, and the motor base 716 is fixedly connected with the die cutting support frame 701; the lifting slide rail 718 is vertically installed on the side wall of the motor base 716, and the lifting slide plate 717 is slidably installed on the lifting slide rail 718; an output shaft of the first die cutting motor 715 is connected with a lifting screw, a lifting screw nut is arranged on the lifting screw, the lifting screw nut is fixed on the back of a lifting sliding plate 717, and the lifting sliding plate 717 is fixedly connected with a die cutting upper seat 707. Therefore, by the rotation of the first die cutting motor 715, the lifting slide 717 can be driven to ascend and descend to drive the die cutting upper seat 707 to ascend and descend, and the pole piece is die-cut by the relative movement of the die cutting upper seat 707 and the die cutting lower seat 708.

In this embodiment, the die cutting driving device further includes a vertical connecting plate 719; the bottom of the lifting sliding plate 717 is provided with a horizontal transverse connecting plate 720, the top of the vertical connecting plate 719 is provided with two rollers along the vertical direction, the transverse connecting plate 720 is clamped between the two rollers, and the bottom of the vertical connecting plate 719 is fixedly connected with the die cutting upper seat 707. Through the design of the structure, when the position of one lower bottom plate 709 or two lower bottom plates 709 is adjusted, the vertical connecting plate 719 and the lifting sliding plate 717 can be displaced in the horizontal direction, but the lifting sliding plate 717 is not influenced to drive the die cutting upper seat 707 to ascend and descend; the structure design is exquisite, and the position of the die cutting upper seat 707 and the die cutting lower seat 708 can be conveniently adjusted. In addition, a bearing seat is fixedly installed on the upper surface of the second horizontal plate 705, and the top end of the first screw 713 and the top end of the second screw 714 are installed in the corresponding bearing seats.

In addition, before the pole piece feeding assembly 1004, an upper dust removing assembly 60 and a lower dust removing assembly 1005 are further provided, as shown in fig. 9, the structures of the upper dust removing assembly 60 and the lower dust removing assembly 1005 are completely the same, and only the structure of the upper dust removing assembly 60 is described in detail in this embodiment. The upper dust removing structure comprises a dust removing motor 601, a motor fixing plate 602, a guide block fixing plate 603 and a dust removing block 604; dust removal motor 601 fixed mounting on motor fixed plate 602, guide block fixed plate 603 sets up between motor fixed plate 602 and dust removal piece 604, the motor shaft of dust removal motor 601 passes through guide block fixed plate 603, be connected with dust removal piece 604, in this embodiment, this dust removal motor 601 is flexible motor, can drive dust removal piece 604 and carry out elevating movement, when needs adsorb the pole piece, dust removal motor 601 drives dust removal piece 604 and stretches out, after the dust removal is accomplished, dust removal piece 604 releases the pole piece, dust removal motor 601 drives dust removal piece 604 and retracts to in order to remove dust to next pole piece. Further, a plurality of strip-shaped guide blocks 605 are fixedly arranged on one surface of the guide block fixing plate 603 facing the dust removal block 604, a plurality of guide holes are formed in the dust removal block 604, and the tail ends of the strip-shaped guide blocks 605 are inserted into the guide holes of the dust removal block 604; the one side of the dust removing block 604 back to the guide block fixing plate 603 is provided with a plurality of strip-shaped exhaust ports 606, the strip-shaped exhaust ports 606 are parallel, and a plurality of vacuum suction holes 607 are arranged between the adjacent strip-shaped exhaust ports 606.

In this embodiment, three parallel strip-shaped exhaust ports 606 are disposed on the dust removing block 604, the strip-shaped exhaust ports 606 are used for blowing air to the outside, and the vacuum suction holes 607 between adjacent strip-shaped exhaust ports 606 are all arranged in a straight line. When the pole piece needs to be dedusted, the dedusting block 604 presses on the pole piece, the pole piece is sucked under the action of the vacuum suction hole 607, the pole piece is prevented from falling, and meanwhile, the strip-shaped exhaust port 606 blows air outwards, so that dedusting of the pole piece is realized.

The upper dust removing structure with the structure of the utility model can remove dust at any position of the pole piece due to the plurality of strip-shaped air outlets 606 arranged on the dust removing block 604 side by side, and meanwhile, the pole piece can be sucked by the plurality of vacuum sucking holes 607 to avoid the pole piece from falling off in the dust removing process; compared with the technical scheme of realizing dust removal through the hairbrush in the prior art, the dust removal method has better dust removal effect and improves the dust removal efficiency, and two pieces of the pole piece can be removed through the two upper dust removal structures with the same structure.

In addition, in the above embodiment, a plurality of guide sleeves 608 are fixedly mounted on the motor fixing plate 602, and a guide rod 609 is disposed in each guide sleeve 608, and a bottom end of the guide rod 609 abuts against the guide block fixing plate 603; when the dust removal motor 601 drives the dust removal block 604 to retract, the strip-shaped guide block 605 can guide the movement of the dust removal block 604, so that the position of the dust removal block 604 is prevented from being deviated.

While the preferred embodiments of the present invention have been described, the present invention is not limited to the above embodiments, and those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present invention, and such equivalent modifications or substitutions are intended to be included within the scope of the present invention as defined by the appended claims.

Claims

1. The utility model provides an integrative equipment of cross cutting lamination which characterized in that: the device comprises a pole piece die cutting mechanism, a pole piece conveying mechanism, a positive pole piece feeding mechanism, a negative pole piece feeding mechanism, a diaphragm unreeling mechanism and a double lamination table mechanism;

2. A die-cut lamination integrity device as claimed in claim 1, wherein: the first lamination table and the second lamination table are identical in structure; the first lamination table comprises a lamination seat body and a pressing component, the central rotating shaft penetrates through the center of the lamination seat body, the pressing components are arranged on the opposite side walls of the lamination seat body, and each pressing component comprises a pressing driving device, a rotating shaft, a rotating cam, a translation sliding block and a pressing plate;

3. A die-cut lamination integrity device as claimed in claim 2, wherein: the first lamination table further comprises a lifting assembly, the lifting assembly comprises a lifting sliding plate and a lifting driving device, the lifting sliding plate is arranged on the side wall opposite to the lamination base body, and the lifting driving device is used for driving the lifting sliding plate to slide on the side wall of the lamination base body in a lifting mode;

the rotating shaft and the pressing sheet driving device are both arranged on the lifting sliding plate, a translation sliding rail is fixedly arranged on the lifting sliding plate, and the translation sliding block is slidably arranged on the translation sliding rail.

4. A die-cut lamination integrity device as claimed in claim 3, wherein: the lifting driving device comprises a lifting motor, a transmission belt, a lifting screw rod, a lifting block and a lifting slide rail;

the lifting motor is fixed on the inner wall of the lamination seat body, two ends of the lifting screw rod are rotatably installed on the inner wall of the lamination seat body, the lifting screw rod is matched with the lifting block, and the transmission belt is sleeved between an output wheel of the lifting motor and a rotating wheel positioned at one end of the lifting screw rod; the lifting block is fixedly connected with the lifting sliding plate, the lifting sliding rail is arranged on the outer wall of the lamination seat body, and the lifting sliding plate is slidably arranged on the lifting sliding rail;

5. A die-cut lamination integrity device as claimed in claim 2, wherein: the lamination seat body comprises a top plate and two fixed side plates which are oppositely arranged, the top plate is fixedly arranged at the tops of the two fixed side plates, and the lamination frame is arranged on the upper surface of the top plate;

6. A die-cut lamination integrity device as claimed in claim 1, wherein: the structure of the positive plate feeding mechanism is the same as that of the negative plate feeding mechanism, wherein the positive plate feeding mechanism comprises a working platform, a feeding assembly, a tray transverse moving assembly and a material returning assembly;

7. A die-cut lamination integrity device as claimed in claim 6, wherein: a first transition wheel is arranged below the gap of the first side vertical plate, a first supporting wheel is arranged on the first side vertical plate between the two longitudinal conveying belts, and the feeding conveying belt bypasses from the lower part of the first transition wheel and bypasses from the upper part of the first supporting wheel;

8. A die-cut lamination integrity device as claimed in claim 1, wherein: the pole piece die-cutting mechanism comprises a fixed box body, and a pole piece feeding assembly, a forming die-cutting assembly, a pole lug die-cutting assembly and a pole piece feeding assembly which are sequentially arranged on the side wall of the fixed box body;

9. A die-cut lamination integrity device as claimed in claim 8, wherein: the tab die-cutting assembly comprises a die-cutting support frame, a first die-cutting assembly, a second die-cutting assembly and a position adjusting assembly;

10. A die-cut lamination integrity device as claimed in claim 9, wherein: the die cutting driving device comprises a first die cutting motor, a motor base, a lifting sliding plate, a lifting sliding rail, a lifting screw rod and a lifting screw rod nut; the first die-cutting motor is fixed on the motor seat body, and the motor seat body is fixedly connected with the die-cutting support frame; the lifting slide rail is arranged on the side wall of the motor seat body along the vertical direction, and the lifting slide plate is arranged on the lifting slide rail in a sliding manner; an output shaft of the first die cutting motor is connected with a lifting screw rod, a lifting screw rod nut is arranged on the lifting screw rod and fixed on the back of a lifting sliding plate, and the lifting sliding plate is fixedly connected with a die cutting upper seat;