CN110054030B

CN110054030B - Alloy foil film coiling device

Info

Publication number: CN110054030B
Application number: CN201910398571.8A
Authority: CN
Inventors: 王奇; 王敏雪; 立群; 谷爱俊; 程晓龙; 洪万里
Original assignee: Anhui Metalfoil New Material Co ltd
Current assignee: Anhui Metalfoil New Material Co ltd
Priority date: 2019-05-14
Filing date: 2019-05-14
Publication date: 2021-03-16
Anticipated expiration: 2039-05-14
Also published as: CN110054030A

Abstract

The invention discloses an alloy foil film coiling device, which relates to the technical field of alloy foil film processing and comprises the following components: the device comprises a rack, a driving device and a control device, wherein a chute is arranged on the rack; the first air expansion shaft is rotatably connected to the rack; the driving part is in power connection with the first air expansion shaft; the bracket is positioned inside the rack and is in sliding connection with the sliding groove; the two ends of the first inflatable shaft are provided with rotating connecting parts, the outer diameter of each rotating connecting part is larger than that of the first inflatable shaft, the two ends of the first inflatable shaft are provided with rotating connecting parts, and the outer diameter of each rotating connecting part is larger than that of the first inflatable shaft. Compared with the prior art, the method greatly reduces the operation steps of the alloy foil film winding, and saves a large amount of time, thereby improving the production efficiency and reducing the labor intensity of workers.

Description

Alloy foil film coiling device

Technical Field

The invention relates to the technical field of alloy foil film processing, in particular to an alloy foil film winding device.

Background

The iron-nickel and iron-nickel-chromium alloy has high magnetic conductivity, low coercive force and good protective and decorative properties, and is a good soft magnetic material and a packaging material. The magnetic performance of the alloy is enhanced along with the increase of the iron content, the cost can be saved by replacing expensive nickel with iron to produce the high-iron alloy, particularly, the iron-nickel alloy with the iron content of 63-64 percent has extremely low thermal expansion coefficient, and the high-iron alloy is widely used as components of precise instruments, optical instruments and electronic equipment and is also widely applied to aerospace aviation, military weapons, microwave communication, color TV shadow masks and petroleum transportation containers.

The iron-nickel alloy can be prepared by various methods, such as smelting and casting, sputtering and film forming, double-roller ultra-cold and the like. Compared with these methods, the electrodeposition method has some unique advantages, such as convenient operation, controllable width and thickness of the produced alloy foil, and easy preparation of a large amount of thin film materials.

The electrodeposition method is generally to arrange a cathode roller in an electrolytic cell, rotate the cathode roller at a constant speed so as to adsorb metal ions in an electrolyte onto the cathode roller, and continuously electrodeposit an alloy foil film on the cathode roller; after the alloy foil film is formed, the alloy foil film is required to be peeled from a cathode roller, and the alloy foil film is subjected to procedures of cleaning, drying, edge cutting, rolling and the like.

Most of the existing winding mechanisms wind foil films through a rotating roller, the roller is mostly fixed in a bearing seat, and the bearing seat is fixed on a machine shell through a bolt, so that the winding and unwinding of the roller need to repeatedly disassemble and assemble the bolt, the roller is disassembled from the machine shell, then a roll of foil films on the roller is pulled out, and the roller needs to be reassembled after being pulled out; this mechanism causes the production speed to be severely slowed.

Disclosure of Invention

The invention aims to provide an alloy foil film winding device, which solves the problems of complex operation and low production efficiency of the existing alloy foil film winding in the background technology, and can reduce the operation steps of alloy foil film winding so as to improve the production efficiency.

In view of the above object, the present invention provides an alloy foil film winding apparatus including:

the device comprises a rack, a driving device and a control device, wherein a chute is arranged on the rack;

the first air expansion shaft is rotatably connected to the rack;

the driving part is in power connection with the first air expansion shaft;

the bracket is positioned inside the rack and is in sliding connection with the sliding groove;

the two ends of the first air expansion shaft are provided with rotating connecting parts, the outer diameter of each rotating connecting part is larger than that of the first air expansion shaft, the first air expansion shaft after ventilation is driven by the driving part to rotate, the first air expansion shaft winds the alloy foil film, when the alloy foil film is wound, an air source of the first air expansion shaft is removed, the reset diameter of the first air expansion shaft is reduced, and the alloy foil film falls onto the bracket.

Optionally, the driving portion includes a first motor, the first motor is fixedly connected to the frame, a driving gear is fixedly connected to a rotating shaft of the first motor, the driving gear is engaged with a driven gear, and the driven gear is fixedly connected to one end of the first air expansion shaft.

Optionally, the inside of frame still rotates and is connected with the tensioning rod, tensioning rod power is connected with the regulation part, the height that the regulation part is used for adjusting the tensioning rod.

Optionally, the regulating part includes the roof-rack, two sets of link of bottom fixedly connected with of roof-rack, two sets of link are hollow structure, the connection that can reciprocate respectively at the both ends of tensioning rod is on two sets of link, the top of roof-rack is equipped with the second motor, the second motor has the pivot through the coupling joint, two sets of lines of fixedly connected with in the pivot are taken turns, and is two sets of the stay cord has all been twined on the line, the one end of stay cord is passed the top of roof-rack and link and the one end fixed connection of tensioning rod, still be equipped with pressure sensor on the tensioning rod, pressure sensor and second motor electric connection have the control part.

Optionally, the winding device further includes a coated paper supply mechanism, and the coated paper supply mechanism is configured to attach a layer of coated paper to the alloy foil when the first air-expansion shaft winds the alloy foil.

Optionally, the coated paper supply mechanism includes a second inflatable shaft rotatably connected to the frame, the second inflatable shaft is provided with coated paper, the second inflatable shaft is further connected to a pre-tightening portion, and the pre-tightening portion is used for tightening the coated paper during operation.

Optionally, the pre-tightening part comprises a fixing column, the other end of the fixing column is rotatably connected with the frame and is fixedly connected with a pre-tightening gear, the other end of the fixed column is fixedly connected with a pre-tightening gear, the pre-tightening gear is meshed with a rack, the rack is connected in the rack in a sliding way, one end of the rack is fixedly connected with a return spring, one end of the return spring, which is far away from the rack, is fixedly connected on the rack, wherein, one end of the fixed column and one end of the second air expansion shaft are wrapped with a pre-tightening spring which is provided with a bulge, the pre-tightening part also comprises a stop block corresponding to the bulge, the stop block is fixedly connected in the frame, the bulge and the stop block are both provided with magnets, when the protrusion is in contact with the stopper, the stopper presses the protrusion, so that the pre-tightening spring is expanded.

Optionally, the bracket is provided in plurality.

As can be seen from the above, when the air-inflated automatic winder works, the driving part is started to drive the ventilated first air-inflated shaft to rotate, the first air-inflated shaft winds up the alloy foil film, when the alloy foil film is wound up, the air source of the first air-inflated shaft is removed, the reset diameter of the first air-inflated shaft is reduced, the alloy foil film at the moment just falls on the bracket, the outer diameter of the reset first air-inflated shaft is not in contact with the inner diameter of the alloy foil film, and the first air-inflated shaft can be conveniently taken out at the moment to complete the unwinding work, then the bracket is removed and the first air-inflated shaft is mounted again, optionally, a plurality of brackets are arranged, and the empty bracket is moved to the lower part of the first air-inflated shaft, so that a new winding operation can be started.

Compared with the prior art, the method greatly reduces the operation steps of the alloy foil film winding process, saves a large amount of time, improves the production efficiency and reduces the labor intensity of workers.

Drawings

Fig. 1 is a schematic structural diagram of a winding device according to an embodiment of the present invention;

FIG. 2 is a top view of the first inflatable shaft of FIG. 1;

FIG. 3 is a schematic structural diagram of an adjusting portion according to an embodiment of the present invention;

FIG. 4 is a side view of the preloaded gear of FIG. 1;

fig. 5 is a side view of the projection of fig. 4.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to specific embodiments and the accompanying drawings.

An alloy foil film winding apparatus comprising: the device comprises a rack, a driving device and a control device, wherein a chute is arranged on the rack; the first air expansion shaft is rotatably connected to the rack; the driving part is in power connection with the first air expansion shaft; the bracket is positioned inside the rack and is in sliding connection with the sliding groove; the two ends of the first air expansion shaft are provided with rotary connecting parts, and the outer diameter of each rotary connecting part is larger than that of the first air expansion shaft.

When the device works, the driving part is started, the driving part drives the ventilated first air expansion shaft to rotate, the first air expansion shaft winds the alloy foil film, after the alloy foil film is wound, an air source of the first air expansion shaft is removed, the reset diameter of the first air expansion shaft is reduced, the alloy foil film at the moment just falls onto the bracket, the outer diameter of the reset first air expansion shaft is not in contact with the inner diameter of the alloy foil film, the first air expansion shaft can be conveniently taken out at the moment to complete the roll-down work, then the bracket is moved away, the first air expansion shaft is mounted again, and optionally, a plurality of brackets are arranged, and the empty bracket is moved below the first air expansion shaft, so that a new winding operation can be started.

As shown in fig. 1, in some embodiments, an alloy foil film winding apparatus includes: the device comprises a rack 1, wherein the rack 1 is of a frame-shaped structure, and a sliding groove 11 is formed in the rack 1; the chute 11 is rectangular, and the first air expansion shaft 12 is rotatably connected to the rack 1; a driving part 2 which is in power connection with the first air expansion shaft 12; the bracket 4 is positioned inside the frame 1 and is connected with the sliding chute 11 in a sliding way; specifically, the bracket 4 has a connection end which is clamped in the sliding groove 11 and is slidably connected with the sliding groove 11, wherein the two ends of the first pneumatic shaft 12 have rotation connection portions 13, and the outer diameter of the rotation connection portions 13 is larger than that of the first pneumatic shaft 12.

When the device works, the driving part 2 is started, so that the driving part 2 drives the ventilated first air expansion shaft 12 to rotate, the first air expansion shaft 12 winds an alloy foil film, after the alloy foil film is wound, an air source of the first air expansion shaft 12 is removed, the reset diameter of the first air expansion shaft 12 is reduced, the alloy foil film at the moment just falls on the bracket 4, the outer diameter of the reset first air expansion shaft 12 is not in contact with the inner diameter of the alloy foil film, the first air expansion shaft 12 can be conveniently taken out at the moment because the outer diameter of the rotating connecting part 13 is larger than the outer diameter of the first air expansion shaft 12, the unwinding work is completed, then the bracket 4 is moved away, the first air expansion shaft 12 is installed again, and optionally, a plurality of brackets 4 are arranged, and the empty brackets 4 are moved below the first air expansion shaft 12, so that a new winding operation can be started.

As shown in fig. 2, in some embodiments, the driving portion 2 includes a first motor 21, the first motor 21 is fixedly connected to the frame 1, a driving gear 22 is fixedly connected to a rotating shaft of the first motor 21, the driving gear 22 is engaged with a driven gear 23, and the driven gear 23 is fixedly connected to one end of the first air expansion shaft 12. The during operation drives driving gear 22 through first motor 21 work and rotates, and driving gear 22 drives driven gear 23 and rotates to drive first inflatable shaft 12 and rotate, realize the rolling operation of first inflatable shaft 12.

As shown in fig. 3, in some embodiments, a tension roller 31 is rotatably connected inside the frame 1, the tension roller 31 is dynamically connected with an adjusting part 3, and the adjusting part 3 is used for adjusting the height of the tension roller 31.

Optionally, the adjusting part 3 comprises a top frame 32, the top frame 32 is fixed by a support frame (not shown in the figure), two groups of connecting frames 33 are fixedly connected with the bottom of the top frame 32, the two groups of connecting frames 33 are both hollow structures, the two ends of the tension stick 31 are respectively connected with two groups of connecting frames 33 which can move up and down, the top of the top frame 32 is provided with a second motor 34, the second motor 34 is connected with a rotating shaft 35 through a coupler, the rotating shaft 35 is rotatably connected with a bracket 39, the bottom of the bracket 39 is fixedly connected with the top of the top frame 32, two groups of wire wheels 36 are fixedly connected on the rotating shaft 35, pull ropes 37 are wound on the two groups of wire wheels 36, one end of the pull rope 37 passes through the top of the top frame 32 and the connecting frame 33 and is fixedly connected with one end of the tension stick 31, the tension roller 31 is further provided with a pressure sensor 38, and the pressure sensor 38 and the second motor 34 are electrically connected with a control part.

The alloy foil membrane passes through a pressure sensor 38, the pressure sensor 38 obtains a pressure signal of the alloy foil membrane, when the pressure value is larger than the preset range, the pressure sensor 38 obtains a first signal and sends the first signal to the control part, the control part controls the second motor 34 to transmit the positive force, so that the wire wheel 36 pays off the wire, the roller 31 is tensioned by the gravity of the roller to move downwards, thereby reducing the tension of the alloy foil film, when the pressure value is smaller than the preset range, the pressure sensor 38 obtains a second signal and sends the second signal to the control part, the control part controls the second motor 34 to reversely transmit the signal, so that the wire wheel 36 takes up the wire and drives the tension rod 31 to move upwards, thereby increasing the tension of the alloy foil membrane, continuously adjusting the tension of the alloy foil membrane to maintain the tension of the alloy foil membrane in a proper range, therefore, the rolling effect of the alloy foil film is guaranteed, and the problem that the normal rolling of the alloy foil film is influenced by overlarge or undersize tension of the alloy foil film is avoided.

As shown in fig. 1, 4 and 5, in some embodiments, the winding device further includes a coated paper supply mechanism 5, and the coated paper supply mechanism 5 is configured to attach a layer of coated paper 51 to the alloy foil film when the first air-expanding shaft 12 winds the alloy foil film.

Optionally, the coated paper supply mechanism 5 includes a second inflatable shaft 52 rotatably connected to the frame 1, the coated paper 51 is disposed on the second inflatable shaft 52, and the second inflatable shaft 52 is further connected to a pre-tightening portion, which is used for tightening the coated paper 51 during operation.

When the rolling operation is performed, the first air expansion shaft 12 rolls the alloy foil film and the coated paper 51 at the same time, the coated paper 51 is located on the inner side of the alloy foil film, and the coated paper 51 plays a role in protecting the alloy foil film, so that friction between the alloy foil films is avoided, and the surface quality of the alloy foil film is not affected.

In some embodiments, the pre-tightening portion includes a fixed column 53, one end of the fixed column 53 is rotatably connected with one end of the second inflatable shaft 52, the other end of the fixed column 53 is rotatably connected with the frame 1 and is fixedly connected with a pre-tightening gear 54, the pre-tightening gear 54 is engaged with a rack 55, the rack 55 is slidably connected in the frame 1, one end of the rack 55 is fixedly connected with a return spring 56, and one end of the return spring 56, which is far away from the rack 55, is fixedly connected to the frame 1, wherein one end of the fixed column 53 and one end of the second inflatable shaft 52 are wrapped with a pre-tightening spring 57, the pre-tightening spring 57 has a protrusion 58 thereon, the pre-tightening portion further includes a stopper 59 corresponding to the protrusion 58, the stopper 59 is fixedly connected in the frame 1, magnets are arranged on the protrusion 58 and the stopper 59, and when the protrusion 58 is in contact with the stopper 59, the stop 59 presses against the projection 58, so that the pretensioned spring 57 expands.

When the winding operation is performed, the pre-tightening spring 57 locks the second air-expanding shaft 52 at the beginning, the coated paper 51 drives the second air-expanding shaft 52 to rotate, so that the fixing column 53 is driven to rotate by the locking spring, the pre-tightening gear 54 is driven to rotate by the rotation of the fixing column 53, the pre-tightening gear 54 drives the rack 55 to rotate, the rack 55 compresses the return spring 56, the coated paper 51 rotating in this way needs to overcome the elastic force of the return spring 56, so that the coated paper 51 can be tensioned, the coating effect of the coated paper 51 is ensured, when the protrusion 58 is in contact with the stopper 59, the stopper 59 extrudes the protrusion 58, so that the pre-tightening spring 57 is opened, at the moment, the suction force of the two magnets and the friction force between the second air-expanding shaft 52 and the pre-tightening spring 57 are greater than the elastic force of the return spring 56, at the moment, the second air-expanding, the coated paper 51 no longer provides the steering force, and the elasticity of the return spring 56 is greater than the attraction of the two magnets, and the return spring 56 pushes the fixed column 53 to rotate through the connection relation, so that the second air expansion shaft 52 is driven to rotate to tension the coated paper 51 again. Therefore, the laminating paper 51 can be tensioned through the design of the pre-tightening part, and the rolling effect of the laminating paper 51 during rolling is guaranteed.

Those of ordinary skill in the art will understand that: the discussion of any embodiment above is meant to be exemplary only, and is not intended to intimate that the scope of the disclosure, including the claims, is limited to these examples; within the idea of the invention, also technical features in the above embodiments or in different embodiments may be combined and there are many other variations of the different aspects of the invention as described above, which are not provided in detail for the sake of brevity. Therefore, any omissions, modifications, substitutions, improvements and the like that may be made without departing from the spirit and principles of the invention are intended to be included within the scope of the invention.

Claims

1. An alloy foil film winding device, comprising:

the first air expansion shaft is rotatably connected to the rack;

the driving part is in power connection with the first air expansion shaft;

the two ends of the first air expansion shaft are provided with rotating connecting parts, the outer diameter of each rotating connecting part is larger than that of the first air expansion shaft, the first air expansion shaft is driven by the driving part to rotate after ventilation, the first air expansion shaft winds up the alloy foil film, when the alloy foil film is wound, an air source of the first air expansion shaft is removed, the reset diameter of the first air expansion shaft is reduced, and the alloy foil film falls onto the bracket;

the winding device further comprises a coated paper supply mechanism, and the coated paper supply mechanism is used for attaching a layer of coated paper to the alloy foil film when the alloy foil film is wound by the first air-expansion shaft;

the laminating paper supply mechanism comprises a second air expansion shaft which is rotatably connected to the rack, laminating paper is arranged on the second air expansion shaft, the second air expansion shaft is also connected with a pre-tightening part, and the pre-tightening part is used for tensioning the laminating paper during working;

the pre-tightening part comprises a fixing column, the other end of the fixing column is rotatably connected with the rack and is fixedly connected with a pre-tightening gear, the other end of the fixing column is fixedly connected with the pre-tightening gear, the pre-tightening gear is meshed with a rack, the rack is slidably connected in the rack, one end of the rack is fixedly connected with a reset spring, one end of the reset spring, which is far away from the rack, is fixedly connected with the rack, one end of the fixed column and one end of the second air expansion shaft are wrapped with the pre-tightening spring, a protrusion is arranged on the pre-tightening spring, the pre-tightening part further comprises a stop block corresponding to the protrusion, the stop block is fixedly connected in the rack, magnets are arranged on the protrusion and the stop block, and when the protrusion is in contact with the stop block, the stop block extrudes the.

2. An alloy foil film take-up device according to claim 1, wherein: the driving portion comprises a first motor, the first motor is fixedly connected to the rack, a driving gear is fixedly connected to a rotating shaft of the first motor, the driving gear is meshed with a driven gear, and the driven gear is fixedly connected to one end of the first air expansion shaft.

3. An alloy foil film take-up device according to claim 1, wherein: the inside of frame still rotates and is connected with the tensioning rod, tensioning rod power is connected with the regulation part, the height that the regulation part is used for adjusting the tensioning rod.

4. An alloy foil film take-up device according to claim 3, wherein: the adjusting part comprises a top frame, two groups of connecting frames are fixedly connected to the bottom of the top frame, the two groups of connecting frames are of hollow structures, the two ends of the tensioning rod can be connected to the two groups of connecting frames in a vertical mode respectively, a second motor is arranged at the top of the top frame, the second motor is connected with a rotating shaft through a coupling, two groups of wire wheels are fixedly connected to the rotating shaft, pull ropes are wound on the wire wheels, one ends of the pull ropes penetrate through the tops of the top frame and the connecting frames and the one ends of the tensioning rod, pressure sensors are further arranged on the tensioning rod, and the pressure sensors and the second motor are electrically connected with a control part.

5. An alloy foil film take-up device according to claim 1, wherein: the bracket is provided in plurality.