CN217941522U - Equipment for slitting and forming ultra-narrow precise nickel alloy strip - Google Patents

Abstract

The utility model is suitable for a battery connection piece technical field provides a super narrow accurate nickel alloy strip cuts equipment for shaping, including supporting component, pay-off subassembly, transport locating component and cutting subassembly, the nickel alloy strip twines on the material wheel, and the rotation of second motor drives two-way threaded rod and rotates and drive two movable blocks and move on two-way threaded rod and change the distance between two material grooves, adapts to the use of the nickel alloy area of different sizes; pneumatic cylinder downstream can drive the suppression cutter and carry out the compression moulding to the nickel alloy area on the suppression seat, infra-red transmitter and infrared receiver can prevent that the cutter from taking place the skew when descending, automatic correction when taking place the skew, it causes the waste to prevent to suppress the nickel alloy area after the cutter skew, waste material nickel alloy area after the suppression is corrected through the die mould between second roller and the second commentaries on classics roller, avoid the suppression cutter suppression to cause the suppression to warp to the nickel alloy area, the nickel alloy area after the suppression gets into and transports on the gyro wheel and supply follow-up recycle.

Description

Equipment for slitting and forming ultra-narrow precise nickel alloy strip

Technical Field

The utility model belongs to the technical field of the battery connection piece, especially, relate to a shaping equipment is cut to super narrow accurate nickel alloy strip.

Background

Nickel alloy is the main material for making battery tabs, which are devices for transmitting current, and are generally rectangular, trapezoidal, triangular, stepped, and the like. It can be used as a device for transmitting current, and has the function of preventing the parts which are not welded from being connected by soldering tin, and the reflow soldering is realized by a solder mask layer. The tin water after rolling on the whole surface of the board can be used for wetting the bare circuit board without the solder mask layer to be welded, and the part with the solder mask layer can not be wetted with tin. The battery connecting sheet is widely applied to the industries of 18650 lithium batteries, 18650 battery packs, nickel-cadmium hydride batteries, lithium ion batteries, mobile phone batteries, notebook batteries, mobile power batteries, button batteries, power battery packs, electric vehicle batteries and the like.

Although the existing equipment for slitting and molding the nickel alloy strip improves the production efficiency, the nickel alloy strip needs to be taken manually and then cut and pressed, and the mode is simple and has poor efficiency; for the ultra-narrow precise nickel alloy, due to the problem of the positioning precision of the cutting knife during slitting, the forming position of the battery pole piece is easy to deviate, the waste of the nickel alloy strip can be caused, and the production cost of the battery pole piece is improved; the ultra-narrow and precise nickel strip to be cut is often deformed at the periphery of the waste nickel strip due to the cutting force action of the cutting knife, so that inconvenience is brought to subsequent recycling and processing.

SUMMERY OF THE UTILITY MODEL

The utility model provides a super narrow accurate nickel alloy strip cuts equipment for shaping aims at solving the problem that prior art exists.

The utility model is realized in such a way that the equipment for cutting and forming the ultra-narrow precise nickel alloy strip comprises a supporting component, a feeding component, a conveying and positioning component and a cutting component;

the supporting assembly comprises four supporting legs which are distributed in a matrix shape, the four supporting legs are vertically arranged, top plates are fixedly arranged on the top surfaces of the four supporting legs, and through grooves are formed in the top plates;

the feeding assembly comprises a first support, the first support is fixedly arranged on the top surface of the top plate, a first motor is fixedly arranged in the middle of the rear side surface of the first support, and the output end of the first motor penetrates through the first support and is fixedly connected with a material wheel;

the conveying positioning assembly comprises a second motor, the second motor is fixedly arranged on the outer side surface of the top plate, the second motor is positioned on one side of the first support, the output end of the second motor is fixedly connected with a bidirectional threaded rod, the bidirectional threaded rod is accommodated in the inner space of the through groove, a limiting block is fixedly arranged in the middle of the bidirectional threaded rod, two moving blocks which are distributed at intervals are sleeved on the bidirectional threaded rod, the two moving blocks are positioned on two sides of the limiting block, an electric telescopic rod is fixedly arranged in the middle of the top surface of each moving block, and a material groove is fixedly arranged on the top surface of the electric telescopic rod;

the cutting component comprises a second support, the second support is located electric telescopic handle is kept away from one side of first support, the second support is fixed to be located the roof top surface, the fixed first fixed plate that is equipped with of second support leading flank intermediate position, the fixed pneumatic cylinder that is equipped with of first fixed plate top surface, the pneumatic cylinder output runs through first fixed plate and fixed connection suppression cutter, suppression cutter below is equipped with the suppression seat, the suppression seat with second support fixed connection, the fixed third motor and the fourth motor that are equipped with relative interval distribution of second support trailing flank, the third motor runs through the first roller that rolls of second support and fixed connection, first roller below is equipped with first rotor, first rotor fixed connection the second support, the fourth motor runs through second support and fixed connection second roller, second roller below is equipped with the second rotor, second rotor fixed connection the second support, first bottom surface is fixed and is equipped with a plurality of infrared transmitters, suppression seat top surface is fixed and is equipped with a plurality of infrared receivers.

Preferably, the second support is kept away from one side of electric telescopic handle is equipped with the transportation subassembly, the transportation subassembly includes second fixed plate and third fixed plate, the second fixed plate is fixed to be located the second support is kept away from on electric telescopic handle's the side, the third fixed plate is equipped with two, two the relative interval distribution of third fixed plate, the third fixed plate is fixed to be located on the second fixed plate, two the activity is equipped with a plurality of gyro wheels between the third fixed plate, and is a plurality of the gyro wheel is followed the even interval distribution of third fixed plate extending direction.

Preferably, the plurality of infrared emitters and the plurality of infrared receivers are arranged in one-to-one correspondence, and the corresponding infrared emitters and the corresponding infrared receivers are located on the same vertical plane.

Preferably, the material wheel is wound with a nickel alloy strip.

Preferably, a fixed block is fixedly arranged on the inner wall of the through groove, and the bidirectional threaded rod is movably connected with the fixed block.

Preferably, the middle positions of the four support legs are fixedly provided with a rib beam, and the top surface of the rib beam is fixedly provided with a material receiving disc;

four the landing leg bottom surface all is fixed and is equipped with the universal wheel, four the universal wheel is the matrix distribution.

The beneficial effects of the utility model are that:

the utility model discloses the electric telescopic handle who sets up can adjust the height in material groove, makes the height in material groove and the highly keeping unanimous of material wheel transported substance material, guarantees that the nickel alloy area can not warp in transportation process, and the rotatory movable block that drives of second motor moves on the two-way threaded rod, can change the distance between two material grooves, can adapt to the transport demand in the nickel alloy area of different widths in a flexible way.

The utility model discloses the third motor that sets up is rotatory to drive first roller and is rotated, because the nickel alloy area presss from both sides at first roller and first commentaries on classics between the roller, can make the nickel alloy area when being press forming like this, keep the planarization in nickel alloy area, after the nickel alloy area is accomplished by the suppression, roll roller and second commentaries on classics roller through the second, under the rotation of fourth motor, can level and correct once more to the waste material nickel alloy area after the suppression, prevent that the suppression cutter suppression from leading to the fact the suppression to warp to waste material nickel alloy area, influence follow-up recovery reuse rate.

The utility model discloses the infra-red transmitter and the infrared receiver that set up can prevent that the suppression cutter from taking place the skew when descending, can correct automatically when taking place the skew, and the skew caused the nickel alloy area extravagant when preventing the suppression cutter from taking the suppression to the nickel alloy.

Drawings

Fig. 1 is a front view of the overall structure of the present invention;

fig. 2 is a top view of the feeding assembly of the present invention;

fig. 3 is a side sectional view of the conveying positioning assembly of the present invention;

figure 4 is a top view of the slitting assembly and the transport assembly of the present invention.

In the figure: 1. a support assembly; 11. a support leg; 12. a top plate; 121. a through groove; 13. a reinforcing beam; 14. a take-up pan; 15. a universal wheel; 2. a feeding assembly; 21. a first support; 22. a first motor; 23. a material wheel; 3. a conveying positioning component; 31. a second motor; 32. a bidirectional threaded rod; 33. a moving block; 34. an electric telescopic rod; 35. a material groove; 36. a limiting block; 37. a fixed block; 4. a slitting assembly; 41. a second support; 42. a first fixing plate; 43. a hydraulic cylinder; 44. pressing a cutter; 45. a third motor; 451. a first roll; 452. a first rotating roller; 46. a fourth motor; 461. a second roll; 462. a second rotating roller; 47. pressing a base; 48. an infrared emitter; 49. an infrared receiver; 5. a transport assembly; 51. a second fixing plate; 52. a third fixing plate; 53. and a roller.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

Referring to fig. 1-4, the present invention provides a technical solution: an ultra-narrow precision nickel alloy strip slitting and forming device comprises a supporting component 1, a feeding component 2, a conveying and positioning component 3 and a slitting component 4;

the supporting assembly 1 comprises four supporting legs 11 distributed in a matrix shape, the four supporting legs 11 are vertically arranged, top plates 12 are fixedly arranged on the top surfaces of the four supporting legs 11, and through grooves 121 are formed in the top plates 12;

the feeding component 2 comprises a first support 21, the first support 21 is fixedly arranged on the top surface of the top plate 12, a first motor 22 is fixedly arranged in the middle of the rear side surface of the first support 21, and the output end of the first motor 22 penetrates through the first support 21 and is fixedly connected with a material wheel 23;

the conveying and positioning assembly 3 comprises a second motor 31, the second motor 31 is fixedly arranged on the outer side surface of the top plate 12, the second motor 31 is positioned on one side of the first support 21, the output end of the second motor 31 is fixedly connected with a bidirectional threaded rod 32, the bidirectional threaded rod 32 is accommodated in the inner space of the through groove 121, a limiting block 36 is fixedly arranged in the middle of the bidirectional threaded rod 32, two moving blocks 33 which are distributed at intervals are sleeved on the bidirectional threaded rod 32, the two moving blocks 33 are positioned on two sides of the limiting block 36, an electric telescopic rod 34 is fixedly arranged in the middle of the top surface of each moving block 33, and a material groove 35 is fixedly arranged on the top surface of each electric telescopic rod 34;

the slitting assembly 4 comprises a second support 41, the second support 41 is located on one side of the electric telescopic rod 34 far away from the first support 21, the second support 41 is fixedly arranged on the top surface of the top plate 12, a first fixing plate 42 is fixedly arranged in the middle of the front side surface of the second support 41, a hydraulic cylinder 43 is fixedly arranged on the top surface of the first fixing plate 42, the output end of the hydraulic cylinder 43 penetrates through the first fixing plate 42 and is fixedly connected with a pressing cutter 44, a pressing seat 47 is arranged below the pressing cutter 44, the pressing seat 47 is fixedly connected with the second support 41, a third motor 45 and a fourth motor 46 which are distributed at intervals are fixedly arranged on the rear side surface of the second support 41, the third motor 45 penetrates through the second support 41 and is fixedly connected with a first rolling roller 451, a first rotating roller 452 is arranged below the first rolling roller 451, the first rotating roller 452 is fixedly connected with the second support 41, the fourth motor 46 penetrates through the second support 41 and is fixedly connected with a second rolling roller 461, a second rotating roller 462 is arranged below the second rolling roller 461, the second rotating roller 462 is fixedly connected with the bottom surface 41, a plurality of infrared emitters 48 are fixedly arranged on the first fixing plate 42, and a plurality of infrared receivers 49 are arranged on the pressing seat.

In the present embodiment, a nickel alloy strip is wound around the material wheel 23; threaded holes are formed in the moving blocks 33 and are matched with the bidirectional threaded rod 32, so that the second motor 31 rotates to drive the bidirectional threaded rod 32 to rotate to drive the two moving blocks 33 to move on the bidirectional threaded rod 32, the distance between the two material grooves 35 can be changed, and the width between the two material grooves 35 is adjusted to adapt to the use of nickel alloy belts with different sizes; the nickel alloy belt extends from the material wheel 23 and sequentially passes through the material groove 35, the space between the first rolling roller 451 and the first rotating roller 452, the top surface of the pressing seat 47 and the space between the second rolling roller 461 and the second rotating roller 462, the third motor 45 and the fourth motor 46 can drive the nickel alloy belt to move by rotating, the hydraulic cylinder 43 can drive the pressing cutter 44 to press and form the nickel alloy belt on the pressing seat 47 by moving downwards, the infrared transmitter 48 and the infrared receiver 49 can prevent the pressing cutter 44 from deviating when descending, can automatically correct when deviating, and prevent the nickel alloy belt from being wasted due to the deviation when the pressing cutter 44 presses the nickel alloy belt; the pressed waste nickel alloy strip passes through the space between the second roller 461 and the second roller 462 to be flattened and reshaped, so that the pressing deformation of the waste nickel alloy caused by pressing by the pressing cutter 44 is avoided, and finally the waste nickel alloy strip enters the roller 53 to be transported for subsequent recycling.

Further, one side of the second support 41 far away from the electric telescopic rod 34 is provided with a transportation assembly 5, the transportation assembly 5 comprises a second fixing plate 51 and a third fixing plate 52, the second fixing plate 51 is fixedly arranged on the side of the second support 41 far away from the electric telescopic rod 34, the third fixing plates 52 are provided with two parts, the two third fixing plates 52 are distributed at intervals relatively, the third fixing plate 52 is fixedly arranged on the second fixing plate 51, a plurality of rollers 53 are movably arranged between the two third fixing plates 52, and the plurality of rollers 53 are distributed at intervals uniformly along the extension direction of the third fixing plates 52.

In the present embodiment, after the nickel alloy strip is completely pressed by the press tool 44 on the press bed 47, the nickel alloy strip is reshaped by the second roller 461 and the second roller 462 and then moved to the roller 53 for transportation.

Further, the plurality of infrared emitters 48 and the plurality of infrared receivers 49 are arranged in a one-to-one correspondence, and the corresponding infrared emitters 48 and the corresponding infrared receivers 49 are located on the same vertical plane.

In this embodiment, the infrared emitter 48 and the infrared receiver 49 can prevent the pressing tool 44 from shifting when it descends, and can automatically correct the shifting, thereby preventing the nickel alloy strip from being wasted due to the shifting when the pressing tool 44 presses the nickel alloy strip.

Further, a nickel alloy strip is wound on the material wheel 23.

In this embodiment, the nickel alloy strip is wound on the material rack on the material wheel 23.

Further, a fixing block 37 is fixedly arranged on the inner wall of the through groove 121, and the bidirectional threaded rod 32 is movably connected with the fixing block 37.

In the present embodiment, it is avoided that the bidirectional threaded rod 32 is changed in direction by gravity, and the movement block 33 cannot be moved by the rotation of the second motor 31.

Furthermore, a rib beam 13 is fixedly arranged in the middle of the four supporting legs 11, and a material receiving disc 14 is fixedly arranged on the top surface of the rib beam 13; the bottom surfaces of the four supporting legs 11 are all fixedly provided with universal wheels 15, and the four universal wheels 15 are distributed in a matrix manner.

In the present embodiment, the connecting sheet after slitting can be housed in the take-up tray 14; the universal wheels 15 facilitate the movement and the parking of the whole equipment.

The utility model discloses a theory of operation and use flow: the utility model discloses after installing, set up the winding of nickel alloy strip on material wheel 23, it can drive two movable blocks 33 and move on two-way threaded rod 32 to start the rotatory two-way threaded rod 32 that drives of second motor 31, thereby can change the distance between two material grooves 35, thereby adjust the use in the not unidimensional nickel alloy area of width adaptation between two material grooves 35, the nickel alloy area extends from material wheel 23, pass through material groove 35 in proper order, first roll between roller 451 and the first change roller 452, it rolls between roller 461 and the second change roller 462 to suppress seat 47 top surface and second, third motor 45 and fourth motor 46 are rotatory to drive first roll roller 451 and second roll roller 461 and rotate, because the centre gripping of nickel alloy area is between first roll roller 451 and first change roller 452 and the second rolls between roller 461 and the second change roller 462, thereby it removes to drive the nickel alloy area, pneumatic cylinder 43 moves down and can drive suppression cutter 44 and carry out the suppression shaping to the nickel alloy area on the suppression seat 47, the connection piece after the suppression takes up by take over 14, the transmitter and the second can prevent that the infrared receiver 48 and the infrared receiver from taking place the waste when the offset receiver and correcting the infrared cutter and taking place the waste material and correcting the infrared cutter and the waste of the alloy area and the pressing the waste of the nickel alloy area, it takes place to suppress the waste material and press the waste to the nickel alloy area on the suppression cutter to prevent the nickel alloy area 44 after the suppression cutter to take place.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (6)

1. A super narrow accurate nickel alloy strip cuts equipment for shaping which characterized in that: comprises a supporting component (1), a feeding component (2), a conveying and positioning component (3) and a slitting component (4);

the supporting assembly (1) comprises four supporting legs (11) distributed in a matrix manner, the four supporting legs (11) are vertically arranged, top plates (12) are fixedly arranged on the top surfaces of the four supporting legs (11), and through grooves (121) are formed in the top plates (12);

the feeding assembly (2) comprises a first support (21), the first support (21) is fixedly arranged on the top surface of the top plate (12), a first motor (22) is fixedly arranged in the middle of the rear side surface of the first support (21), and the output end of the first motor (22) penetrates through the first support (21) and is fixedly connected with a material wheel (23);

the conveying and positioning assembly (3) comprises a second motor (31), the second motor (31) is fixedly arranged on the outer side surface of the top plate (12), the second motor (31) is positioned on one side of the first support (21), the output end of the second motor (31) is fixedly connected with a bidirectional threaded rod (32), the bidirectional threaded rod (32) is accommodated in the inner space of the through groove (121), a limit block (36) is fixedly arranged at the middle position of the bidirectional threaded rod (32), two movable blocks (33) which are distributed at intervals are sleeved on the bidirectional threaded rod (32), the two movable blocks (33) are positioned on two sides of the limit block (36), an electric telescopic rod (34) is fixedly arranged at the middle position of the top surface of the movable block (33), and a material groove (35) is fixedly arranged on the top surface of the electric telescopic rod (34);

the slitting component (4) comprises a second support (41), the second support (41) is located the electric telescopic rod (34) is far away from one side of the first support (21), the second support (41) is fixedly arranged on the top surface of the top plate (12), a first fixing plate (42) is fixedly arranged at the middle position of the front side surface of the second support (41), a hydraulic cylinder (43) is fixedly arranged on the top surface of the first fixing plate (42), the output end of the hydraulic cylinder (43) penetrates through the first fixing plate (42) and a pressing cutter (44) fixedly connected with the same, a pressing seat (47) is arranged below the pressing cutter (44), the pressing seat (47) is fixedly connected with the second support (41), a third motor (45) and a fourth motor (46) which are distributed at opposite intervals are fixedly arranged on the rear side surface of the second support (41), the third motor (45) penetrates through the second support (41) and a first rolling roller (451) fixedly connected with the same, a first rolling roller (452) is arranged below the first rolling roller (451), a second rolling roller (462) is fixedly connected with the second support (41), and a second roller (462) is connected with the second roller (462), a plurality of infrared emitters (48) are fixedly arranged on the bottom surface of the first fixing plate (42), and a plurality of infrared receivers (49) are fixedly arranged on the top surface of the pressing seat (47).

2. The ultra-narrow precision nickel alloy strip slitting and molding device according to claim 1, characterized in that: keep away from second support (41) one side of electric telescopic handle (34) is equipped with transportation subassembly (5), transportation subassembly (5) include second fixed plate (51) and third fixed plate (52), second fixed plate (51) are fixed to be located second support (41) are kept away from on the side of electric telescopic handle (34), third fixed plate (52) are equipped with two, two third fixed plate (52) interval distribution relatively, third fixed plate (52) are fixed to be located on second fixed plate (51), two the activity is equipped with a plurality of gyro wheels (53) between third fixed plate (52), and is a plurality of gyro wheel (53) are followed third fixed plate (52) extending direction is even interval distribution.

3. The ultra-narrow precision nickel alloy strip slitting and molding device according to claim 1, characterized in that: the plurality of infrared emitters (48) and the plurality of infrared receivers (49) are arranged in a one-to-one correspondence mode, and the corresponding infrared emitters (48) and the corresponding infrared receivers (49) are located on the same vertical plane.

4. The ultra-narrow precision nickel alloy strip slitting and molding device according to claim 1, characterized in that: and a nickel alloy strip is wound on the material wheel (23).

5. The ultra-narrow precision nickel alloy strip slitting and molding device according to claim 1, characterized in that: fixed block (37) are fixedly arranged on the inner wall of the through groove (121), and the bidirectional threaded rod (32) is movably connected with the fixed block (37).

6. The ultra-narrow precision nickel alloy strip slitting and molding device according to claim 1, characterized in that: a rib beam (13) is fixedly arranged in the middle of each of the four support legs (11), and a material receiving disc (14) is fixedly arranged on the top surface of each rib beam (13);

four all fixed universal wheel (15) that are equipped with of landing leg (11) bottom surface, four universal wheel (15) are the matrix distribution.

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