CN220392802U - Coiling machine for nanocrystalline strip with automatic traction structure - Google Patents

Abstract

The utility model relates to the technical field of winding equipment, and discloses a winding machine for nanocrystalline strips, which is provided with an automatic traction structure. This coiler for nanocrystalline strip with automatic traction structure realizes automatic traction through motor two and the collocation of electric piston, realizes automatic feeding and coiling to nanocrystalline strip through traction mechanism, has improved the degree of automation of production to guaranteed stability and the uniformity of coiling quality, through the slip that uses spring, spout and pivoted plate, can make the circular arc board can stretch out and draw back on the movable tank, collocation with outside extrusion equipment, thereby realize seamless connection and take out, this kind of design makes nanocrystalline strip can not produce scattered or loose condition at the coiling in-process, has improved the uniformity of coiling.

Description

Coiling machine for nanocrystalline strip with automatic traction structure

Technical Field

The utility model relates to the technical field of winding equipment, in particular to a winding machine for a nanocrystalline strip with an automatic traction structure.

Background

The nanocrystalline strip winder is a device specially used for processing nanocrystalline strips. Nanocrystalline tapes are materials with special structures and properties that are commonly used in high-tech fields such as electronics, sensors, energy storage devices, etc. The nanocrystalline strip has higher specific surface area and excellent electrical, magnetic, thermal and other characteristics, so that the nanocrystalline strip has wide application potential in a plurality of fields.

The existing nanocrystalline strip needs to be manually pulled in the winding process, namely, the feeding and the winding of the nanocrystalline strip are manually guided. This requires continuous monitoring and intervention by the operator, increasing labor costs and operational difficulties, and at the same time, there may be unstable factors such as uneven pulling force or inaccurate guiding, resulting in reduced winding quality or damage to the nanocrystalline strip, and after winding is completed, there may be a certain trouble in removing the wound nanocrystalline strip from the nanocrystalline strip winder, careful and careful handling may be required to prevent damage or kinking of the nanocrystalline strip due to its special nature and size, and flexibility and deformability of the nanocrystalline strip also increase difficulties in the handling process, and additional tools or skills may be required to maintain the shape and integrity of the nanocrystalline strip.

Disclosure of Invention

(one) solving the technical problems

In order to overcome the defects in the prior art, the utility model provides a coiler for a nanocrystalline strip with an automatic traction structure, so that the problems that the nanocrystalline strip in the prior art needs to be manually drawn in the coiling process, namely, the feeding and coiling of the nanocrystalline strip are manually guided, continuous monitoring and intervention are required by operators, the labor cost and the operation difficulty are increased, meanwhile, unstable factors such as uneven pulling force or inaccurate guiding exist in manual operation, the coiling quality of the nanocrystalline strip is reduced or damaged, and after the coiling is finished, certain trouble exists in the process of taking the coiled nanocrystalline strip from the nanocrystalline strip coiler, careful and careful operation is required to prevent the nanocrystalline strip from being damaged or knotted due to the special property and size of the nanocrystalline strip, the flexibility and the deformability of the nanocrystalline strip also increase the difficulty in the taking process, and additional tools or skills are required to maintain the shape and the integrity of the nanocrystalline strip are solved.

(II) technical scheme

In order to achieve the above purpose, the present utility model provides the following technical solutions: the winder for the nanocrystalline strip with the automatic traction structure comprises a base, wherein the upper end of the base is fixedly connected with a fixing plate, a winding mechanism is arranged on the fixing plate, a sliding groove is formed in the upper end of the base, and a traction mechanism is arranged at the upper end of the base;

the winding mechanism comprises a movable groove, an arc plate, a limiting plate, a first motor, a two-way screw rod, a rotating disc, a rotating plate, a rotating motor, a positioning plate, a spring and a sliding groove, wherein the sliding groove is formed in the rear end of the base.

Preferably, the fixed plate is provided with a movable groove, the upper end and the lower end of the inner part of the movable groove are movably connected with arc plates, the arc plates are provided with two arc plates, the sliding grooves are provided with rotating plates in a sliding mode, the rear ends of the rotating plates are fixedly connected with rotating motors, the output ends of the rotating motors extend to the front ends of the rotating plates and are fixedly connected with rotating discs, and the rotating discs are rotationally connected with the rotating plates.

Through the technical scheme, the motor rotates to drive the bidirectional screw rod to rotate, so that the two circular arc plates move inwards to clamp the nanocrystalline strip, and the situation that dislocation and knot are tied during winding is avoided.

Preferably, the upper and lower both sides fixedly connected with limiting plate of rolling disc front end, the limiting plate is provided with two, the upper end fixedly connected with motor one of limiting plate, the output of motor one extends to the inside rotation connection of limiting plate has two-way lead screw, two-way lead screw and limiting plate rotate to be connected with, two circular arc board and two-way lead screw threaded connection, the rear end fixedly connected with of rolling plate has a plurality of springs, the one end fixedly connected with locating plate () of rolling plate is kept away from to the spring, locating plate and base fixed connection.

Through above-mentioned technical scheme, drive the rolling disc through rotating the motor and rotate, thereby the rolling disc rotates on the rolling plate and drives two limiting plates and rotate to make the circular arc board rotate in the movable groove, take up.

Preferably, the traction mechanism comprises an electric piston, a push block, a connecting plate, an anti-slip roller, a supporting block and a second motor, wherein the electric piston is fixedly connected to the right side of the upper end of the base, the push block is fixedly connected to the left end of the electric piston, and the push block is in sliding connection with the sliding groove.

Through the technical scheme, the electric piston drives the pushing block, and the pushing block slides on the sliding groove to drive the supporting block, so that the strip between the anti-skid rollers is fed into the gap between the two circular arc plates, and guiding and positioning are performed.

Preferably, the upper end fixedly connected with supporting shoe of kicking block, fixedly connected with connecting plate on the supporting shoe, the upper and lower both sides rotation of connecting plate front end is connected with anti-skidding gyro wheel, anti-skidding gyro wheel is provided with two, the upper end fixedly connected with motor two of supporting shoe, the output and the anti-skidding gyro wheel fixed connection of motor two.

Through above-mentioned technical scheme, put into the strip between two anti-skidding gyro wheels, thereby rotate and drive anti-skidding gyro wheel rotation through motor two, thereby make two anti-skidding gyro wheels rotate together through driving an anti-skidding gyro wheel to pay-off.

Compared with the prior art, the utility model provides the winding machine for the nanocrystalline strip with the automatic traction structure, which has the following beneficial effects:

1. this coiler for nanocrystalline strip with automatic traction structure realizes automatic traction through motor two and the collocation of electric piston, realizes automatic feeding and coiling to nanocrystalline strip through traction mechanism, this eliminates the demand that the manual work carried out the traction, has improved the degree of automation of production, and automatic traction can ensure the even traction and the accurate position of nanocrystalline strip to stability and uniformity of coiling quality have been guaranteed.

2. This coiler for nanocrystalline strip with automatic traction structure through the slip that uses spring, spout and rotor plate, can make the circular arc board flexible on the movable groove to match with outside extrusion equipment to realize seamless connection and take out, this kind of design makes nanocrystalline strip can not produce scattered or loose condition in the coiling process, ensures closely and evenly of coiling result, has improved the quality and the uniformity of coiling.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic top view of the present utility model;

FIG. 3 is a schematic rear view of the present utility model;

FIG. 4 is a schematic side view of the present utility model;

FIG. 5 is a schematic diagram of the front view of the present utility model

In the figure: 1. a base; 2. a fixing plate; 3. a winding mechanism; 4. a sliding groove; 5. a traction mechanism; 301. a movable groove; 302. an arc plate; 303. a limiting plate; 304. a first motor; 305. a two-way screw rod; 306. a rotating disc; 307. a rotating plate; 308. a rotating motor; 309. a positioning plate; 310. a spring; 311. a chute; 501. an electric piston; 502. a pushing block; 503. a connecting plate; 504. an anti-slip roller; 505. a support block; 506. and a second motor.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Embodiment one:

as shown in fig. 1-4, the present utility model provides a technical solution: the winder for the nanocrystalline strip with the automatic traction structure comprises a base 1, wherein the upper end of the base 1 is fixedly connected with a fixed plate 2, a winding mechanism 3 is arranged on the fixed plate 2, a sliding groove 4 is formed in the upper end of the base 1, and a traction mechanism 5 is arranged at the upper end of the base 1;

the winding mechanism 3 comprises a movable groove 301, an arc plate 302, a limiting plate 303, a first motor 304, a bidirectional screw rod 305, a rotating disc 306, a rotating plate 307, a rotating motor 308, a positioning plate 309, a spring 310 and a sliding groove 311, wherein the sliding groove 311 is formed in the rear end of the base 1.

Specifically, the fixed plate 2 is provided with a movable groove 301, the upper end and the lower end of the inside of the movable groove 301 are movably connected with arc plates 302, the arc plates 302 are provided with two, a sliding chute 311 is provided with a rotating plate 307, the rear end of the rotating plate 307 is fixedly connected with a rotating motor 308, the output end of the rotating motor 308 extends to the front end of the rotating plate 307 and is fixedly connected with a rotating disc 306, and the rotating disc 306 is rotationally connected with the rotating plate 307. The device has the advantages that the motor I304 rotates to drive the bidirectional screw rod 305 to rotate, so that the two circular arc plates 302 move inwards to clamp the nanocrystalline strip, and the situation that dislocation and knot are generated during winding is avoided.

Specifically, the upper and lower both sides fixedly connected with limiting plate 303 of rolling disc 306 front end, limiting plate 303 is provided with two, limiting plate 303's upper end fixedly connected with motor one 304, motor one 304's output extends to limiting plate 303's inside rotation is connected with two-way lead screw 305, two-way lead screw 305 rotates with limiting plate 303 to be connected, two circular arc boards 302 and two-way lead screw 305 threaded connection, the rear end fixedly connected with of rolling plate 307 has a plurality of springs 310, the one end fixedly connected with locating plate 309 of rolling plate 307 is kept away from to spring 310, locating plate 309 and base 1 fixed connection. The advantage is that through the rotation motor 308 drive rotation disk 306 rotation, thereby the rotation disk 306 rotates on the rotation plate 307 and drives two limiting plates 303 rotation to make circular arc plate 302 rotate in movable groove 301, take up.

Embodiment two:

as shown in fig. 2-5, as an improvement over the previous embodiment. Specifically, the traction mechanism 5 includes an electric piston 501, a push block 502, a connecting plate 503, an anti-slip roller 504, a supporting block 505, and a second motor 506, where the right side of the upper end of the base 1 is fixedly connected with the electric piston 501, the left end of the electric piston 501 is fixedly connected with the push block 502, and the push block 502 is slidably connected with the sliding groove 4. The advantage is that electric piston 501 drives push block 502, and push block 502 slides on sliding groove 4 thereby driving supporting block 505 to make the strip between anti-skidding gyro wheel 504 send into the clearance of two circular arc boards 302, thereby carry out the direction location.

Specifically, the upper end fixedly connected with supporting shoe 505 of ejector pad 502, fixedly connected with connecting plate 503 on the supporting shoe 505, the upper and lower both sides of connecting plate 503 front end rotate and are connected with anti-skidding gyro wheel 504, and anti-skidding gyro wheel 504 is provided with two, and the upper end fixedly connected with motor two 506 of supporting shoe 505, the output and the anti-skidding gyro wheel 504 fixed connection of motor two 506. The advantage is, put into the strip between two anti-skidding gyro wheels 504, thereby rotate through motor two 506 and drive anti-skidding gyro wheel 504 and rotate, thereby make two anti-skidding gyro wheels 504 rotate together through driving an anti-skidding gyro wheel 504 to pay-off.

When the device is used, a strip is placed between two anti-slip rollers 504 through external conveying equipment, a motor II 506 is started, the motor II 506 rotates to drive the anti-slip rollers 504 to rotate on a connecting plate 503, the anti-slip rollers 504 act relatively, so that the strip is conveyed, an electric piston 501 is started, the electric piston 501 drives a push block 502 to slide on a sliding groove 4, and accordingly a supporting block 505 is driven to move, the strip is conveyed into a gap between the two arc plates 302, a motor I304 is started, the motor I304 rotates to drive a bidirectional screw 305 to rotate on a limiting plate 303, the bidirectional screw 305 rotates to drive the two arc plates 302 to move in a movable groove 301, the two arc plates 302 clamp the strip, a rotating motor 308 is started, the rotating motor 308 rotates to drive a rotating disc 306 to rotate on a rotating plate 307, the two limiting plates 303 rotate, the arc plates 302 rotate to wind the strip, after winding, the arc plates 302 are extruded by external extrusion equipment, the rotating plate 307 slides on a sliding groove 311 to enable a spring 310, the positioning plate 309 is used for fixing the spring 310, the first extrusion part is extruded to clamp the strip, the strip is clamped by the second arc plates, the second extrusion part is well, and the strip is prevented from falling off, and the fault tolerance of the device is prevented from being connected, and the strip is well cut, and the strip is prevented from falling down.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a nanocrystalline strip is with coiler with automatic traction structure, includes base (1), its characterized in that: the upper end of the base (1) is fixedly connected with a fixed plate (2), a winding mechanism (3) is arranged on the fixed plate (2), a sliding groove (4) is formed in the upper end of the base (1), and a traction mechanism (5) is arranged at the upper end of the base (1);

the winding mechanism (3) comprises a movable groove (301), an arc plate (302), a limiting plate (303), a first motor (304), a bidirectional screw rod (305), a rotating disc (306), a rotating plate (307), a rotating motor (308), a positioning plate (309), a spring (310) and a sliding groove (311), wherein the sliding groove (311) is formed in the rear end of the base (1).

2. The coiler for nanocrystalline strip provided with an automatic traction structure according to claim 1, characterized in that: the movable groove (301) has been seted up on fixed plate (2), the inside upper and lower both ends swing joint of movable groove (301) has circular arc board (302), circular arc board (302) are provided with two, sliding connection has rotor plate (307) on spout (311), the rear end fixedly connected with rotation motor (308) of rotor plate (307), the output of rotation motor (308) extends to the front end fixedly connected with rotor plate (306) of rotor plate (307), rotor plate (306) are connected with rotor plate (307) rotation.

3. A coiler for nanocrystalline strip provided with an automatic traction structure according to claim 2, characterized in that: the utility model discloses a motor, including rotating disk (306), limiting plate (303) are fixed connection in upper and lower both sides of rotating disk (306) front end, limiting plate (303) are provided with two, the upper end fixedly connected with motor (304) of limiting plate (303), the inside rotation that the output of motor (304) extends to limiting plate (303) is connected with two-way lead screw (305), two arc board (302) and two-way lead screw (305) threaded connection, the rear end fixedly connected with spring (310) of rotating plate (307), one end fixedly connected with locating plate (309) of rotating plate (307) are kept away from to spring (310), locating plate (309) and base (1) fixed connection.

4. The coiler for nanocrystalline strip provided with an automatic traction structure according to claim 1, characterized in that: traction mechanism (5) are including electric piston (501), ejector pad (502), connecting plate (503), anti-skidding gyro wheel (504), supporting shoe (505), motor two (506), the right side fixedly connected with electric piston (501) of base (1) upper end, the left end fixedly connected with ejector pad (502) of electric piston (501), ejector pad (502) and sliding tray (4) sliding connection.

5. The coiler for nanocrystalline strip provided with an automatic traction structure according to claim 4, characterized in that: the anti-skid device comprises a pushing block (502), wherein a supporting block (505) is fixedly connected to the upper end of the pushing block (502), a connecting plate (503) is fixedly connected to the supporting block (505), anti-skid rollers (504) are rotatably connected to the upper side and the lower side of the front end of the connecting plate (503), two anti-skid rollers (504) are arranged, a motor II (506) is fixedly connected to the upper end of the supporting block (505), and the output end of the motor II (506) is fixedly connected with the anti-skid rollers (504).