CN219321406U - High-speed lamination table - Google Patents

Abstract

The utility model relates to the technical field of lamination machines and discloses a high-speed lamination table.A base is arranged, a horizontal moving assembly is arranged on the base, a lifting assembly and a jacking assembly are respectively connected with the horizontal moving assembly, and the horizontal moving assembly controls the lifting assembly to move in the horizontal direction; the jacking assembly comprises a lamination table and a jacking motor, wherein pole pieces are placed on the lamination table in a lamination mode, and the jacking motor drives the lamination table to move vertically; the lifting assembly comprises a pressing plate and a lifting motor, and the lifting motor drives the pressing plate to vertically move up and down so as to limit the pole piece. The horizontal and vertical movement of the pressing plate and the vertical movement of the lamination table in the lamination process are controlled by independent driving sources, so that the precision is high, the speed is high, the efficiency is high, the pole pieces are not damaged, and the practicability is wide.

Description

High-speed lamination table

Technical Field

The utility model relates to the technical field of lamination machines, in particular to a high-speed lamination table.

Background

The existing diaphragm lamination machine generally has three modes of completing the movement in the horizontal direction and the vertical direction in the lamination process: 1. the cam mechanism is adopted, and the working principle of the cam mechanism is that the rotation motion of the cam is converted into the curve motion on a plane, but the vertical motion is necessarily accompanied with the horizontal motion in the motion mode, and the horizontal motion can lead to friction between the pressing plate and the pole piece, so that the damage and the reduction of the placement precision of a product are caused, and meanwhile, the cam is easy to block and generate metal dust; 2. the synchronous belt is adopted to translate to realize horizontal movement and the air cylinder is adopted to lift to realize vertical movement, so that the precision is poor and the response is slow; 3. the ball screw mode is adopted, so that the efficiency is low.

Disclosure of Invention

The utility model aims to provide a high-speed lamination table with high placement accuracy and no damage to products, and aims to solve the problems in the prior art.

The utility model is realized in such a way that the high-speed lamination table comprises a base, a horizontal moving assembly is arranged on the base, a lifting assembly and a jacking assembly are respectively connected with the horizontal moving assembly, and the horizontal moving assembly controls the lifting assembly to move in the horizontal direction; the jacking assembly comprises a lamination table and a jacking motor, wherein pole pieces are placed on the lamination table in a lamination mode, and the jacking motor drives the lamination table to move vertically; the lifting assembly comprises a pressing plate and a lifting motor, and the lifting motor drives the pressing plate to vertically move up and down so as to limit the pole piece.

Optionally, the horizontal migration subassembly includes the straight line mounting bracket, installs the horizontal migration motor on the straight line mounting bracket, straight line mounting bracket and translation board sliding connection, horizontal migration motor drive translation board horizontal migration.

Optionally, the horizontal movement motor comprises a rotor and a magnetic track, the magnetic track is mounted on the linear mounting frame, and the translation plate is connected with the rotor.

Optionally, the lifting assembly further comprises a motor mounting seat, the lifting motor is connected with the lifting plate, and the pressing plate is detachably mounted on the lifting plate.

Optionally, the motor mount pad is connected with the translation board, lifter plate and motor mount pad sliding connection.

Optionally, the device further comprises a deviation rectifying assembly, wherein the deviation rectifying assembly comprises a deviation rectifying motor, the deviation rectifying motor is connected with a deviation rectifying fixing plate, an output shaft of the deviation rectifying motor is connected with a first mounting plate, and the first mounting plate is connected with the deviation rectifying plate; the deviation rectifying fixing plate is in sliding connection with the deviation rectifying plate.

Optionally, the output shaft of the jacking motor is connected with a second mounting plate, and the second mounting plate is mounted to one side of the linear mounting frame.

Optionally, the jacking movable plate is slidably connected with the second mounting plate, and the lamination table is mounted on the jacking movable plate through a mounting bracket.

Optionally, the horizontal migration subassembly still includes buffer block and stopper, and buffer block installs to sharp mounting bracket one end, and the stopper is installed in sharp mounting bracket other end, all installs the blotter on buffer block and the stopper.

Optionally, the device further comprises a first sensor assembly, a second sensor assembly, a third sensor assembly and a fourth sensor assembly, wherein the first sensor assembly is used for detecting the initial position of the horizontal moving assembly, the second sensor assembly is used for detecting the initial position of the lifting assembly, the third sensor assembly is used for detecting the initial position of the deviation rectifying assembly, and the fourth sensor assembly is used for detecting the initial position of the jacking assembly.

Compared with the prior art, the horizontal moving assembly is arranged on the base, the lifting assembly and the jacking assembly are respectively connected with the horizontal moving assembly, and the horizontal moving assembly controls the lifting assembly to move in the horizontal direction; the jacking assembly comprises a lamination table and a jacking motor, wherein pole pieces are placed on the lamination table in a lamination mode, and the jacking motor drives the lamination table to move vertically; the lifting assembly comprises a pressing plate and a lifting motor, and the lifting motor drives the pressing plate to vertically move up and down so as to limit the pole piece. The horizontal and vertical movement of the pressing plate and the vertical movement of the lamination table in the lamination process are controlled by independent driving sources, so that the precision is high, the speed is high, the efficiency is high, the pole pieces are not damaged, and the practicability is wide.

Drawings

FIG. 1 is a schematic view of a high speed lamination station provided by an embodiment of the present utility model;

FIG. 2 is an exploded view of a lift assembly according to an embodiment of the present utility model;

FIG. 3 is a schematic view of another angular configuration of a high-speed lamination station provided by an embodiment of the present utility model;

FIG. 4 is an enlarged partial view of the portion "A" of FIG. 3;

fig. 5 is a schematic structural diagram of a jacking assembly (with lamination stations removed) and a deviation rectifying assembly according to an embodiment of the present utility model.

Reference numerals:

1-a base; 101-a base trough; 2-a horizontal movement assembly; 201-a mover; 202-magnetic tracks; 203-a linear mounting rack; 204-translating the plate; 205—a rail; 206-a buffer block; 207-limiting blocks; 208-reinforcing ribs; 3-lifting assembly; 301-lifting motor; 302-lifting plate; 303-a platen; 304-a motor mount; 305-a first slide rail; 4, a deviation correcting component; 401-a deviation rectifying motor; 402, a correction fixing plate; 4021—an installation notch; 403-a first mounting plate; 404-correcting the deviation board; 405-a second slide rail; 406-a slider; 407-fixing a bracket; 5-jacking assembly; 501-jacking a motor; 502-an output shaft; 5021-shaft mounting plate; 503-a second mounting plate; 5031-a first via; 504-lifting the movable plate; 5041-a second through hole; 505-third slide rail; 506-mounting a bracket; 507-lamination station; 508-auxiliary fixation plate; 6-a first sensor assembly; 601-a first detection plate; 602-a first sensor; 7-a second sensor assembly; 701-a second detection plate; 702-a second sensor; 8-a third sensor assembly; 801-a third detection plate; 802-a third sensor; 9-a fourth sensor assembly; 901-fourth test plate; 902-a fourth sensor; 903-slide rail groove.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present utility model, it should be understood that, if there is an azimuth or positional relationship indicated by terms such as "upper", "lower", "left", "right", etc., based on the azimuth or positional relationship shown in the drawings, it is only for convenience of describing the present utility model and simplifying the description, but it is not indicated or implied that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and thus terms describing the positional relationship in the drawings are merely illustrative and should not be construed as limitations of the present patent, and specific meanings of the terms described above may be understood by those skilled in the art according to specific circumstances.

The implementation of the present utility model will be described in detail below with reference to specific embodiments.

Referring to fig. 1 to 5, a preferred embodiment of the present utility model is provided.

The utility model provides a high-speed lamination platform 507, includes base 1, horizontal migration subassembly 2 and lifting unit 3, and horizontal migration subassembly 2 installs in the base groove 101 on base 1, and horizontal migration subassembly 2 is connected with lifting unit 3 and drives lifting unit 3 horizontal migration. In this embodiment, the horizontal moving assembly 2 is provided with two groups, which are respectively mounted at two ends of the base 1; the lifting assembly 3 is provided with two groups, which are respectively mounted on each horizontal movement assembly 2.

The lifting assembly 3 comprises a pressing plate 303, the pressing plate 303 is used for limiting the pole pieces in the lamination process, the pressing plate 303 is moved in the horizontal direction and the vertical direction through the horizontal movement assembly 2 and the lifting assembly 3, the precision is high, the speed is high, the operation is convenient, and the lamination efficiency is greatly improved.

Further, the horizontal moving assembly 2 includes a horizontal moving motor including a mover 201 and a magnetic track 202, and a linear mounting frame 203 to which the magnetic track 202 is mounted. The translation plate 204 is connected with the mover 201, and a clamping groove is formed in the translation plate 204 and is matched with a guide rail 205 mounted on the linear mounting frame 203 to move horizontally. The reinforcing ribs 208 are arranged at the bottom of the linear mounting frame 203, and the reinforcing ribs 208 are fixedly connected to two end faces of the base 1. The horizontal movement motor adopts a linear motor movement mode, and has the advantages of high precision and high speed.

Further, the horizontal moving assembly 2 further includes a buffer block 206 and a stopper 207, wherein the buffer block 206 is mounted on one end of the linear mounting frame 203, and the stopper 207 is mounted on the other end of the linear mounting frame 203. The buffer block 206 is provided with a buffer cushion to prevent the linear mover 201 from moving too fast to generate impact. The limiting block 207 is used for limiting the moving distance of the translation plate 204, and preferably, a buffer pad is mounted on the limiting block 207.

In this embodiment, the lifting assembly 3 includes a lifting motor 301, and the lifting motor 301 is used to drive the pressing plate 303 to move in the vertical direction to press the pole piece and the diaphragm (the diaphragm is used to pack the pole piece), so as to ensure the width of the diaphragm after wrapping the pole piece by adjusting the interval between the pressing plate 303 and the lamination table 507. Preferably, the lifting motor 301 adopts a voice coil motor, the precision is high, the speed is high, and the voice coil motor has a constant voltage mode, so that the pole piece is ensured to be pressed and stabilized without damaging the pole piece.

Specifically, the lift motor 301 is mounted to a motor mount 304 and is connected to a lift plate 302. The pressing plate 303 is detachably mounted to the lifting plate 302 to be lifted and lowered along with the movement of the lifting plate 302 on the first slide rail 305. The first sliding rail 305 is fixed on the motor mounting seat 304.

More specifically, the motor mount 304 is mounted to the translating plate 204, such that the horizontal movement assembly 2 moves the platen 303 horizontally.

In this embodiment, the lifting assembly 5 is further included, where the lifting assembly 5 includes a lifting motor 501 and a lamination table 507, and the lifting motor 501 drives the lamination table 507 to vertically move, so as to ensure that the height of the pole piece and the diaphragm after being placed is the same as the initial height. Preferably, the jacking motor 501 is a servo motor, so that the stress of each layer of pole piece on the lamination table 507 is uniform.

Specifically, the output shaft 502 of the jacking motor 501 is connected to a second mounting plate 503, and the second mounting plate 503 is mounted to the side of the linear mounting frame 203.

Further, the lifting moving plate 504 is slidably connected to the second mounting plate 503 through a third sliding rail 505, so as to realize movement in the vertical direction. Preferably, the third slide rail 505 is a cross roller guide rail 205.

The second mounting plate 503 is provided with a first through hole 5031, the lifting moving plate 504 is provided with a second through hole 5041, a shaft mounting plate 5021 connected with the output shaft 502 is connected with the first through hole 5031 and the second through hole 5041 in a penetrating manner, and the shaft mounting plate 5021 is used for supporting the lifting moving plate 504.

Further, a mounting bracket 506 is further mounted on one side of the lifting moving plate 504, and the upper end of the mounting bracket 506 is connected with a lamination table 507.

Still further, the embodiment further includes a rectifying component 4, where the rectifying component 4 is used for rectifying the deviation of the diaphragm.

Specifically, the deviation rectifying assembly 4 includes a deviation rectifying motor 401, and the deviation rectifying motor 401 is provided with a deviation rectifying fixing plate 402. Meanwhile, an output shaft of the deviation rectifying motor 401 is connected with a first mounting plate 403, the first mounting plate 403 is connected with a deviation rectifying plate 404, and the deviation rectifying motor 401 is started to drive the first mounting plate 403 to move back and forth, so that the deviation rectifying plate 404 is driven to move back and forth, and position rectification is carried out on the diaphragm.

Further, a second sliding rail 405 is installed on the top end of the deviation rectifying fixing plate 402, and the deviation rectifying plate 404 moves on the second sliding rail 405 through a sliding block 406.

In order to better control the moving distance, the present embodiment is further provided with a plurality of sensor assemblies including a first sensor assembly 6, a second sensor assembly 7, a third sensor assembly 8, and a fourth sensor assembly 9. The first sensor assembly 6 is used for detecting the initial position of the horizontal moving assembly 2, the second sensor assembly 7 is used for detecting the initial position of the lifting assembly 3 in the vertical direction, the third sensor assembly 8 is used for detecting the initial position of the deviation correcting assembly 4, and the fourth sensor assembly 9 is used for detecting the initial position of the jacking assembly 5.

Specifically, the first sensor assembly 6 includes a first detection plate 601 and a plurality of first sensors 602, the first detection plate 601 is mounted on the translation plate 204, and the plurality of first sensors 602 are arranged on the guide rail 205; the second sensor assembly 7 comprises a second detection plate 701 and a plurality of second sensors 702, the first detection plate 601 is mounted on the lifting plate 302, and the plurality of second sensors 702 are arranged on the first sliding rail 305 in a separated manner; the third sensor assembly comprises 8 a third detection plate 801 and a plurality of third sensors 802, the third detection plate 801 is mounted on the first mounting plate 403, and the plurality of third sensors 802 are arranged on the deviation rectifying fixing plate 402 in a separated mode; the fourth sensor assembly 9 includes a fourth sensing plate 901 and a plurality of fourth sensors 902, the fourth sensing plate 901 being mounted to the shaft mounting plate 5021, the plurality of fourth sensors 902 being arranged in rows on the rail grooves 903, the rail grooves 903 being mounted to the second mounting plate 503.

Optionally, the horizontal moving assembly 2 and the lifting assembly 3 are both provided with magnetic grids for detecting the moving distance and improving the moving precision.

Optionally, the jacking assembly 5 further includes an auxiliary fixing plate 508, where the auxiliary fixing plate 508 is disposed on the top of the linear moving frame and is mounted on one side of the second mounting plate 503, so as to fix the second mounting plate 503 on the linear mounting frame 203.

Optionally, the fixing plate 402 is provided with a mounting notch 4021, and the plurality of third sensors 802 are separately arranged in the mounting notch 4021.

The working principle of the application is as follows: in the initial state, the platen 303 is moved to the outer region of the lamination table 507. After the electrode plate is placed on the lamination table 507, the lifting motor 301 is turned on, the pressing plate 303 is lifted, the horizontal moving assembly 2 is moved to move the pressing plate 303 until the pressing plate 303 moves to the position above the lamination table 507, the pressing plate 303 is lowered, the electrode plate and the diaphragm can be limited at the moment, and the width of the diaphragm after wrapping the electrode plate can be ensured by adjusting the distance between the pressing plate 303 and the lamination table 507. The press plate 303 moves vertically up and down to press the pole piece and diaphragm so that the diaphragm translates to the other side of the lamination table and the pole pieces are stacked. During lamination, the lift motor 501 drives the lamination table 507 down to place more pole pieces. The horizontal and vertical movements of the pressing plate 303 and the vertical movement of the lamination table 507 in the lamination process are controlled by independent driving sources, so that the precision is high, the speed is high, the efficiency is high, and the practicability is wide.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. The high-speed lamination table is characterized by comprising a base, wherein a horizontal moving assembly is arranged on the base, a lifting assembly and a jacking assembly are respectively connected with the horizontal moving assembly, and the horizontal moving assembly controls the lifting assembly to move in the horizontal direction; the jacking assembly comprises a lamination table and a jacking motor, wherein pole pieces are placed on the lamination table in a laminated mode, and the jacking motor drives the lamination table to vertically move; the lifting assembly comprises a pressing plate and a lifting motor, and the lifting motor drives the pressing plate to vertically move up and down so as to limit the pole piece.

2. The high-speed lamination stage of claim 1, wherein the horizontal movement assembly comprises a linear mounting bracket and a horizontal movement motor mounted on the linear mounting bracket, the linear mounting bracket being slidably coupled to the translating plate, the horizontal movement motor driving the translating plate to move horizontally.

3. The high speed lamination station of claim 2, wherein the horizontal movement motor includes a mover and a magnetic track, the magnetic track being mounted to the linear mount, the translating plate being coupled to the mover.

4. A high speed lamination station as defined in claim 3, wherein said lift assembly further comprises a motor mount, said lift motor being coupled to a lift plate, said pressure plate being removably mounted to said lift plate.

5. The high speed lamination station of claim 4, wherein the motor mount is coupled to the translating plate and the lifter plate is slidably coupled to the motor mount.

6. The high-speed lamination stage of claim 5, further comprising a deviation rectifying assembly, wherein the deviation rectifying assembly comprises a deviation rectifying motor, the deviation rectifying motor is connected with a deviation rectifying fixing plate, an output shaft of the deviation rectifying motor is connected with a first mounting plate, and the first mounting plate is connected with the deviation rectifying plate; the deviation rectifying fixing plate is in sliding connection with the deviation rectifying plate.

7. The high speed lamination station of claim 6, wherein an output shaft of the jacking motor is coupled to a second mounting plate, the second mounting plate being mounted to one side of the linear mounting frame.

8. The high speed lamination station of claim 7, further comprising a jacking travel plate slidably coupled to the second mounting plate, the lamination station being mounted to the jacking travel plate by a mounting bracket.

9. The high-speed lamination stage of claim 8, wherein the horizontal movement assembly further comprises a buffer block and a limiting block, the buffer block is mounted to one end of the linear mounting frame, the limiting block is mounted to the other end of the linear mounting frame, and a buffer pad is mounted to both the buffer block and the limiting block.

10. The high speed lamination station of claim 9, further comprising a first sensor assembly for initial position detection of the horizontal movement assembly, a second sensor assembly for initial position detection of the lifting assembly, a third sensor assembly for initial position detection of the de-rectification assembly, and a fourth sensor assembly for initial position detection of the jacking assembly.

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