CN212608575U - Metal foil material loading equipment - Google Patents

Abstract

The utility model relates to a metal foil material charging equipment. The equipment comprises a coil stock feeding mechanism, a coil stock cutting mechanism and a material receiving platform which are sequentially arranged, wherein the coil stock feeding mechanism is used for lifting a coil stock to an unreeling position, the coil stock cutting mechanism is used for cutting the unreeled coil stock into a set size, and the material receiving platform is used for receiving the cut coil stock or a sheet stock placed on a tray and transferring the coil stock or the sheet stock to the next station. The utility model discloses a coil stock feed mechanism has realized that the automatic lifting of coil stock targets in place, connects the feeding of material platform compatible coil stock and sheet stock, and coil stock cutting mechanism plays and tailors and the intermediate junction effect, and whole equipment has reduced artificial participation, can supply the user to adopt coil stock or sheet stock simultaneously, and equipment integration degree and degree of automation obtain improving, and production efficiency obtains promoting, satisfies the user demand.

Description

Metal foil material loading equipment

Technical Field

The utility model relates to a metal foil material processing equipment especially relates to a metal foil material charging equipment.

Background

At present, copper foil is generally required for producing the circuit board, and the copper foil can be provided by a roll material or a sheet material. When the copper foil is provided by a coil stock, the coil stock needs to be unreeled, then the copper foil with a set size is cut out, and then the next processing production is carried out. When the copper foil is supplied from a sheet stock, the sheet stock is typically already sized and placed in a tray from which it is sent to the next station for further processing. In conventional production equipment, several preorder steps of the copper foil cannot be integrated into one automation, for example, material rolling, material sheet feeding in the same equipment, material rolling needing to be manually lifted to an unreeling position, and the like, are required to be improved.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's defect, and provide a metal foil material charging equipment, can improve integrated level and degree of automation to improve production efficiency.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a metal foil material charging equipment, its includes coil stock feed mechanism, coil stock cutting mechanism and the material receiving platform who arranges in proper order, and coil stock feed mechanism is used for lifting the coil stock to unreeling on the position, and coil stock cutting mechanism is used for cutting the coil stock of unreeling into the settlement size, and the material receiving platform is arranged in accepting the coil stock after cutting or places the sheet stock on the tray and transfers coil stock or sheet stock to next station.

Coil stock feed mechanism includes the board, lifting subassembly and blowing platform are all established on the board, the lifting subassembly includes the lifting motor, two vertical lead screws and elevating platform, two synchronous rotations of lifting motor synchronous drive lead screws, the nut that is equipped with on two lead screws is fixed with the elevating platform respectively, two elevating platforms are with high synchronous lift, the elevating platform is used for supporting the axis both ends of coil stock, the blowing platform is used for placing the coil stock and supplies the coil stock to unreel, the plane perpendicular to lead screw of blowing platform, when the elevating platform remove to with the blowing platform height at the same time, the coil stock can be followed the elevating platform translation to the blowing platform on.

Bearings are respectively arranged at two ends of the coil middle shaft, a guide groove is arranged on the lifting platform, and the bearings are arranged in the guide groove and can roll in the guide groove; the discharging platform is provided with a straight groove corresponding to the guide groove, the tail end of the straight groove is provided with an upward-tilting arc-shaped groove, a rotatable opening and closing pressing block is arranged above the arc-shaped groove, and the pressing block is used for pushing the bearing of the coil stock to the arc-shaped groove and clamping the bearing. The movable end of the pressing block is controlled by an air cylinder to move up and down.

The coil stock cutting mechanism comprises a base, an upper cutter and a lower cutter, wherein the base is provided with an upper sliding plate capable of moving up and down, the upper cutter is arranged on the upper sliding plate, the upper part of the upper cutter is hinged with the upper sliding plate, and the upper cutter can rotate up and down around the hinged part; the lower part of the upper cut-off knife is detachably and fixedly connected with the upper sliding plate, the upper cut-off knife is provided with a detachable upper knife head, and the upper knife head is embedded and fixed in the lower part of the upper cut-off knife.

The upper sliding plate is provided with at least two horizontal cylinders, the output shaft of each horizontal cylinder is connected with the upper cut-off knife, the horizontal cylinders retract to enable the upper cut-off knives and the lower cut-off knives to form vertical shearing when the upper sliding plate descends to cut, and the output shafts stretch out to enable the upper cut-off knives to be separated from the lower cut-off knives when the upper sliding plate ascends.

The upper sliding plate is provided with at least two positioning columns, the positioning columns are arranged on one side of the horizontal cylinder, and the axes of the positioning columns are collinear with the output shaft of the horizontal cylinder; when the output shaft of the horizontal cylinder retracts and drives the upper cutter to rotate to the maximum stroke, the positioning column is abutted against the upper cutter, and the upper cutter descends to form vertical shearing with the lower cutter.

The lower cut-off knife is provided with a lower knife head, the coil stock penetrates through the top surface of the lower knife head, the lower cut-off knife is provided with a transition surface which is flush with the top surface of the lower knife head, and the transition surface is abutted against the other side, opposite to the cutting edge of the lower knife head; the base is also provided with a pressing strip for pressing the coil stock, the pressing strip provides pressing force through an air cylinder, and the coil stock is pressed on the transition surface and the top surface of the lower cutter head through the pressing strip.

The material receiving platform comprises a horizontal material receiving plate capable of ascending and descending up and down, a plurality of fixed top posts with the same height and a material clamping assembly; when the horizontal material receiving plate rises to a position for receiving the coil materials, the ejection column is positioned below the horizontal material receiving plate, and the material clamping assembly is used for clamping the coil materials, pulling out the coil materials along a straight line and placing the cut coil materials on the horizontal material receiving plate; when the horizontal material receiving plate descends to a height lower than the top column, the top column is used for receiving the tray for placing the sheet materials.

The clamping assembly comprises a clamping jaw, a horizontal lead screw and a vertical cylinder, the vertical cylinder is used for driving the clamping jaw to move up and down, and the horizontal lead screw is used for driving the vertical cylinder and the clamping jaw to move horizontally and linearly.

When the horizontal material receiving plate rises to a position for receiving the coil materials, the vertical cylinder drives the clamping jaw to rise to a height higher than that of the horizontal material receiving plate, and when the clamping jaw pulls out the coil materials, a gap is reserved between the coil materials and the horizontal material receiving plate; after the coil stock is cut, the vertical cylinder drives the clamping jaw to descend so as to place the coil stock on the horizontal material receiving plate.

Compared with the prior art, the utility model beneficial effect be: realized the automatic lifting of coil stock through coil stock feed mechanism and target in place, connect the feeding of material platform compatible coil stock and sheet stock, coil stock cutting mechanism plays and tailors and the intermediate junction effect, and whole equipment has reduced artificial participation, can supply the user to adopt coil stock or sheet stock simultaneously, and equipment integration level and degree of automation obtain improving, and production efficiency obtains promoting, satisfies the user demand.

Drawings

Fig. 1 is a general assembly perspective view of the metal foil material loading device of the present invention.

Fig. 2 is the assembly perspective view of the coil feeding mechanism of the utility model.

Fig. 3 is the utility model discloses coil stock feed mechanism's frame and cylinder, clamp plate assembly stereogram.

Fig. 4 is a perspective view of the coil stock and frame assembly of the coil stock feeding mechanism of the present invention.

Fig. 5 is the orthographic projection view of the coil feeding mechanism of the present invention.

Fig. 6 is a sectional view of the driving coil structure of the coil feeding mechanism of the present invention.

Fig. 7 is the utility model discloses coil stock cutting mechanism assembles stereogram.

Fig. 8 is an assembly perspective view of the coil cutting mechanism of the present invention with parts omitted.

Fig. 9 is the utility model discloses coil stock cutting mechanism's last slide and horizontal cylinder, reference column assembly stereogram.

Fig. 10 is a perspective view of the lower cutter of the coil cutting mechanism of the present invention.

Fig. 11 is a perspective view of the upper cutter of the coil cutting mechanism of the present invention.

Fig. 12 is a perspective view of the back side of the coil cutting mechanism.

Fig. 13 is the utility model discloses coil stock cutting mechanism's layering and cylinder assembly stereogram.

Fig. 14 is a perspective view of the material receiving platform of the present invention.

Figure 15 is the utility model discloses connect material platform's level to connect flitch and fore-set assembly stereogram.

Fig. 16 is a perspective view of the material clamping assembly of the material receiving platform of the present invention.

Fig. 17 is a side view of the material receiving platform of the present invention.

It should be noted that, the products shown in the above views are all appropriately reduced/enlarged according to the size of the drawing and the clear view, and the size of the products shown in the views is not limited.

Detailed Description

In order to more fully understand the technical content of the present invention, the technical solution of the present invention will be further described and explained with reference to the specific embodiments.

The embodiment is a metal foil material feeding device, as shown in fig. 1. The metal foil material feeding device comprises a roll material feeding mechanism 100, a roll material cutting mechanism 200 and a material receiving platform 300 which are sequentially arranged. The coil feeding mechanism 100 is configured to lift the coil to the unwinding position. The coil cutting mechanism 200 is used for cutting the unreeled coil into a set size. The receiving platform 300 is used for receiving the cut roll material or the sheet material placed on the tray and transferring the roll material or the sheet material to the next station.

The following describes the roll material feeding mechanism 100, the roll material cutting mechanism 200, and the receiving platform 300 in detail.

The specific structure of the roll feeding mechanism 100 is shown in fig. 2-6. As shown in fig. 2, the roll feeding mechanism 100 includes a machine table 10, a lifting assembly, and a discharging platform 127. The lifting assembly and the discharging platform 127 are both arranged on the machine table 10. The lift assembly includes a lift motor 111, two vertical lead screws 116, and a lift table 119. The lifting motor 111 is arranged above the machine table 10, the lifting motor 111 is connected with a speed reducer 112, the speed reducer 112 drives two horizontal half shafts 113 to rotate, the two horizontal half shafts 113 are respectively connected with a steering gear 115 through a coupler 114, and the two steering gears 115 respectively drive two lead screws 116 to rotate. When the lift motor 111 is activated, the two lead screws 116 rotate synchronously. The lead screw 116 in fig. 2 is covered with a dust cover 117 to keep the lead screw 116 clean. As shown in fig. 2, nuts 118 are provided on both of the lead screws 116, and the nuts 118 move linearly up and down when the lead screws 116 rotate. The two nuts 118 are respectively and fixedly connected with a lifting platform 119, and the two lifting platforms 119 are lifted synchronously at the same height. Each lifting platform 119 is used for supporting one end of the central shaft of the coil stock 125. The two ends of the central shaft of the roll material 125 are respectively provided with a bearing 124, the lifting platform 119 is provided with a vertical plate 120, the vertical plate 120 is provided with a guide groove 121, and the bearings 124 are arranged in the guide groove 121 and can roll in the guide groove 121, so that the roll material 125 can move horizontally along the guide groove 121. Outside the guide groove 121, the riser 120 is provided with a stopper 122, and the stopper 122 is used for preventing the roll 125 from sliding out of the guide groove 121 when moving up and down along with the lifting table 119. The guide slot 121 extends to the stop 122 to form an upwardly arcuate slot 123. As shown in fig. 2, the rear side of the lifting table 119 is provided with a sensing block 137, and the machine table 10 is correspondingly provided with an upper proximity switch 139 and a lower proximity switch 138. When the lifting platform 119 ascends until the sensing block 137 blocks the proximity switch 139, the lifting motor 111 is controlled to stop working, and when the lifting platform 119 descends until the sensing block 137 blocks the proximity switch 138, the lifting motor 111 is controlled to stop working.

In addition, as shown in fig. 2, two upper and lower discharge stages 127 are provided in the machine table 10. The same platform 127 has left and right sides (see fig. 5). The discharging platform 127 is used for placing the roll material 125 and allowing the roll material 125 to be discharged at a constant speed. The plane of the emptying platform 127 is perpendicular to the screw 116. When the lifting platform 119 moves to a level with the discharge platform 127, the coil 125 can be translated from the lifting platform 119 to the discharge platform 127. The purpose of arranging the upper and lower discharging platforms 127 is to unreel the coil 125 of the other discharging platform 127 while replenishing the coil 125 when the coil 125 on one discharging platform 127 is completely unreeled, thereby reducing the waiting time and improving the production efficiency. In other embodiments, more than 2 emptying platforms can be arranged if the space allows. In other embodiments, only one material placing platform may be provided to reduce the equipment cost.

As shown in fig. 2 to 4, the discharging platform 127 is provided with an Contraband-shaped frame 128. The lower rod 129 of the frame 128 is provided with a straight groove 131 corresponding to the guide groove 121, and the upper rod 130 of the frame 128 is hinged with an air cylinder 133. The end of the straight slot 131 is provided with an arc-shaped slot 134 which is tilted upwards. A pressing block 132 which can be opened and closed rotatably is arranged above the arc-shaped groove 134. The movable end of the pressing block 132 is controlled by the air cylinder 133 to move up and down, and the fixed end of the pressing block 132 is hinged with the frame 128. When the lifting platform 119 is level with the discharge platform 127, the guide groove 121 is aligned with the straight groove 131, so that the roll 125 can be translated into the straight groove 131 of the discharge platform 127 directly, as shown in fig. 4. When the bearing 124 of the roll 125 rolls to approach the arc-shaped slot 134, the control cylinder 133 extends, the movable end of the pressing block 132 faces downwards, and the pressing block 132 pushes the bearing 124 of the roll 125 to the arc-shaped slot 134 and clamps the bearing 124, so that the roll 125 cannot translate along the straight slot 131.

As shown in fig. 5, a gear 126 is provided at one end of the central shaft of the roll material 125 and rotates coaxially with the roll material 125. The machine 10 is further provided with motors 135 and 136. The motors 135 and 136 are used for driving the coil material 125 to rotate at a constant speed for unreeling, and can work together with an external coil pulling mechanism. For the coil stock on the upper discharging platform 127, as shown in fig. 6, the motor 135 drives a synchronizing wheel 142 through a coupling 140 and a magnetic particle clutch 141, the synchronizing wheel 142 drives a driving wheel to rotate through a synchronizing belt 143, the driving wheel is meshed with the gear 126, and the driving wheel is used for driving the coil stock 125 to rotate through the gear 126. For the coil material 125 on the lower discharging platform 127, the motor 136 and the same transmission structure are used to drive the coil material 125 to rotate.

The specific structure of the coil cutting mechanism is shown in figures 7-13. And the unreeled coil stock enters a coil stock cutting mechanism to be cut. As shown in fig. 7, the coil cutting mechanism is provided with a base 20, and an upper slide plate 201 which can move up and down is provided on the base 20. The base 20 is provided with two slide rails 202, the back of the upper slide plate 201 is fixed with a corresponding slide seat 203, and the slide seat 203 is connected with the slide rails 202 in a sliding manner. The base 20 is provided with 2 high-precision vertical cylinders 205, and the vertical cylinders 205 are used for driving the upper sliding plate 201 to slide up and down. The upper cutter 204 is arranged on the upper sliding plate 201, the upper part of the upper cutter 204 is hinged with the upper sliding plate 201, and the upper cutter 204 can rotate up and down around the hinged part. The upper cutter 204 is also detachably hinged to the upper sliding plate 201, and the lower part of the upper cutter 204 is detachably fixed to the upper sliding plate 201. As shown in fig. 8 and 9, the upper slide plate 201 is provided with two horizontal cylinders 206, and the two horizontal cylinders 206 are located at positions corresponding to two ends of the upper cutter 204 in the length direction. The output shaft of the horizontal cylinder 206 is detachably connected with the upper cutter 204. When the upper sliding plate 201 descends to cut, the output shaft of the horizontal cylinder 206 retracts, and the lower part of the upper cutter 204 moves towards the horizontal cylinder 206, so that the upper cutter 204 and the lower cutter 211 can form vertical cutting. When the upper sliding plate 201 ascends, the output shaft of the horizontal cylinder 206 extends to make the lower part of the upper cutter 204 move back to the horizontal cylinder 206, so that the upper cutter 204 is separated from the lower cutter 211, and unnecessary friction between the upper cutter 204 and the lower cutter 211 is reduced. The horizontal cylinder 206 mainly controls the small angle rotation of the upper cutter 204, so the connection between the output shaft of the horizontal cylinder 206 and the upper cutter 204 should have a certain flexibility. As shown in fig. 8 and 9, the upper slide plate 201 is provided with two positioning posts 207. The positioning column 207 is provided on the side of the horizontal cylinder 206 and the axis of the positioning column 207 is collinear with the output shaft of the horizontal cylinder 206. When the output shaft of the horizontal cylinder 206 retracts to drive the upper cutter 204 to rotate to the maximum stroke, the positioning column 207 abuts against the upper cutter 204, and at the moment, the upper cutter 204 descends to vertically cut the lower cutter 211. Therefore, the positioning post 207 is used for accurately defining the position of the upper cutter 204 during cutting operation, and avoiding the inaccuracy caused by directly defining the position by using the horizontal air cylinder 206. In addition, as shown in fig. 9, the upper sliding plate 201 is provided with a strip-shaped supporting strip 208, the cut roll material passes through the supporting strip 208, and the two horizontal air cylinders 206 are arranged at the two ends of the supporting strip 208. The supporting strip 208 is also provided with a saw-toothed conducting strip 209.

The base 20 is provided with a removable safety block 210. The safety block 210 includes at least one safety position. When the safety block 210 is located at the safety position, the safety block 210 is used to block the upper slide plate 201 from descending. In the present embodiment, as shown in fig. 8, the safety block 210 is connected to the base 20 as a rotating shaft, that is, the safety block 210 can rotate around the rotating shaft. When the safety block 210 rotates to a vertical safety position (i.e. directly under one side of the upper sliding plate 201), the upper sliding plate 201 and the safety block 210 will abut against each other, so that the upper sliding plate 201 cannot fall down. When the coil stock needs to be pulled out manually, the safety block 210 can be used for supporting the upper sliding plate 201, accidents caused by accidental falling of the upper sliding plate 201 are avoided, and the safety is improved. When the upper cutter head of the upper cutter 204 needs to be replaced, the safety block 210 can be used for propping against the upper sliding plate 201 and then replacing the upper sliding plate, so that the safety coefficient is better. In other embodiments, the safety block can also be transversely translated, and a notch can be arranged on one side of the upper slide plate, so that the safety block can be pushed into the notch to serve as a safety position of the safety block.

As shown in fig. 8, below the upper cutter 204 is a lower cutter 211. As shown in fig. 8 and 10, a lower cutter 211 is detachably fixed with a replaceable elongated lower cutter head 212 by a plurality of screws. As the web passes, it passes over the top surface of the lower blade 212. As shown in fig. 11, the upper cutter 204 is fixed with a detachable and replaceable elongated upper cutter head 215 by a plurality of screws, and the upper cutter head 215 is inserted and fixed in a lower portion of the upper cutter 204. When the upper cutter 204 cooperates with the lower cutter 211 for vertical cutting, the cutting edge 216 of the upper blade 215 moves downward against the outer side of the cutting edge 213 of the lower blade 212, thereby completing guillotine-type cutting.

As shown in fig. 12, the base 20 is further provided with an upper roller 217 which can move up and down and a lower roller 218 which can rotate. The drawn-out web passes between the upper and lower rollers 217 and 218. The upper roller 217 is driven by two lower pressing cylinders 219 to press and clamp the roll with the lower roller 218 synchronously, and the lower roller 218 is driven by a motor 220 to rotate, so that the upper roller 217 and the lower roller 218 can pull the roll. After passing between the upper roller 217 and the lower roller 218, the unwound roll passes through a transition surface 214 of the lower cutter 211 in fig. 10, which is flush with the top surface of the lower blade 212. It can be seen from fig. 4 that the transition surface 214 abuts the opposite side of the cutting edge 213 of the lower cutting insert 212. Above the transition surface 214, a pressing strip 221 for pressing the web is provided. As shown in fig. 12 and 13, the pressing bar 221 is divided into two halves and fixed to a cross bar 222, and the cross bar 222 is driven by a cylinder 223. The air cylinder 223 provides a pressing force to the pressing bar 221 through the cross bar 222. When the cylinder 223 extends, the bead 221 descends and presses the web against the transition surface 214 and the top surface of the lower blade 212. The pressing strip 221 is used for pressing the roll material at the position close to the cutting opening so as to ensure that the cutting opening is smooth.

The specific structure of the receiving platform is shown in fig. 14-17. As shown in fig. 14, the roll cutting mechanism 200 is provided on one side of the receiving platform 300. In the production line, the coil cutting mechanism 200 is upstream of the receiving platform 300. The material clamping assembly 313 of the receiving platform 300 clamps the roll material 302 in the roll material cutting mechanism 200, pulls out the roll material 302 in a straight line, and then cuts the roll material 302 by the roll material cutting mechanism 200. The receiving platform 300 of this embodiment includes a horizontal receiving plate 301 capable of ascending and descending, a plurality of fixed top pillars 304 with the same height, a material clamping assembly 313 and a material discharging assembly. As can be seen from fig. 14 and 15, the horizontal material receiving plates 301 are divided into 4 pieces, the area of the two middle pieces is larger, the area of the two side pieces is smaller, and a linear gap is left between the adjacent horizontal material receiving plates 301. The horizontal material receiving plate 301 is provided with a through hole 305 through which the top pillar 304 passes. There are two rows of ten top columns 304, and thus there are two rows of 10 through holes 305 of the horizontal material receiving plate 301. The horizontal material receiving plate 301 is driven to move up and down by a plurality of cylinders 306 below. As shown in fig. 14 and 15, when the cylinder 306 is fully extended, the horizontal receiving plate 301 is raised to the position of the receiving coil 302, and the top pillar 304 is located below the horizontal receiving plate 301. As shown in fig. 14, the horizontal receiving plate 301 is provided with 8 stopper plates 303 for restricting the position of the coil 302 after being pulled out. When the cylinder 306 in fig. 15 is fully retracted, the horizontal material receiving plate 301 is lowered to a level lower than the top pillars 304, and ten top pillars 304 are inserted through the through holes 305, so that the operator can place the tray on which the material is placed on the top pillars 304 and fix it. To this end, the tray (not shown) may be provided with positioning holes corresponding one-to-one to the top posts 304.

Further, as shown in fig. 14, the blanking assembly includes a lead screw 308, a slide 309, a vertical cylinder 310, and a horizontal frame 311. The blanking assembly is used for sucking cut rolls 302 on the horizontal material receiving plate 301 or sheets in a tray placed on the top column 304, and transferring the cut rolls or sheets to the next station for further processing. The lead screw 308 drives the slide 309 to move linearly, and the vertical cylinder 310 is fixed to the slide 309. The output shaft of the vertical cylinder 310 is fixedly connected with a horizontal frame 311, wherein 6 downward vacuum suction heads 312 are arranged on the horizontal frame 311. When the horizontal frame 311 moves above the coil 302 on the horizontal material receiving plate 301 or above the sheet on the tray, the horizontal frame 311 moves downwards, the vacuum suction head 312 sucks up the coil 302 or the sheet, and the horizontal frame 311 moves outwards in a straight line after moving upwards, so that the transfer of the coil 302 or the sheet is completed.

The material clamping assembly 313 is used for clamping the roll material 302, pulling out the roll material 302 along a straight line and placing the cut roll material 302 on the horizontal material receiving plate 301. As shown in fig. 16, the clamping assembly 313 includes a clamping jaw 314, a horizontal lead screw 315, and a vertical cylinder 316. The horizontal lead screw 315 drives the vertical cylinder 316 and the clamping jaw 314 to move horizontally and linearly through the sliding plate 317, and the vertical cylinder 316 is used for driving the clamping jaw 314 to move up and down. The clamping jaws 314 are three in number and are equidistantly fixed to the slide 317. As can be seen from fig. 14 and 15, the horizontal material receiving plate 301 is divided into four pieces. The jaws 314 are linearly movable in the gaps between adjacent horizontal receiver plates 301. As shown in fig. 14, the horizontal material receiving plate 301 has been raised to the position of the material receiving 302, and the vertical cylinder 316 (fig. 16) drives the clamping jaws 314 to rise to a height higher than the horizontal material receiving plate 301, so that the clamping jaws 314 can clamp the material receiving 302. When the clamping jaws 314 are pulled out of the coil 302 smoothly, there is a gap between the clamping jaws 314 and the horizontal receiving plate 301, so that a gap is left between the coil 302 and the horizontal receiving plate 301 (see fig. 17). After the coil 302 is cut, the vertical cylinder 316 drives the clamping jaws 314 to descend, and the horizontal lead screw 315 continues to push the clamping jaws 314 to advance in the material pulling direction until the coil 302 reaches the position defined by the limiting plate 303, so that the coil 302 is smoothly taken and placed on the horizontal material receiving plate 301 (see fig. 14). Fig. 17 shows the web 302 at a higher elevation than the horizontal draw plate 301 when the jaws 314 are pulling the web 302 from the web cutting mechanism 200. After the jaws 314 are pulled out of the set length of the roll 302, the roll cutting mechanism 200 grips the roll 302 and cuts the roll 302 to obtain a set size of the roll 302.

In addition, as shown in fig. 14, a detecting head 307 is disposed between the receiving platforms 300 of the roll cutting mechanism 200, and the detecting head 307 is mainly used for detecting the thickness of the roll 302 to avoid pulling out a double layer.

In the description of the present invention, it should be noted that the terms "upper", "lower", "top", "bottom", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

The above description is only for the purpose of illustrating the technical content of the present invention by way of example, so as to facilitate the understanding of the reader, but does not represent that the embodiments of the present invention are limited thereto, and any technical extension or re-creation according to the present invention is protected by the present invention.

Claims (10)

1. The utility model provides a metal foil material charging equipment, its characterized in that, it is including the coil stock feed mechanism, coil stock cutting mechanism and the material receiving platform that arrange in proper order, coil stock feed mechanism is used for lifting the coil stock to unreeling on the position, coil stock cutting mechanism is used for cutting the coil stock of unreeling into setting for the size, the material receiving platform is arranged in accepting the coil stock after cutting or places the sheet stock on the tray and transfers coil stock or sheet stock to next station.

2. The metal foil feeding device according to claim 1, wherein the coil feeding mechanism comprises a machine table, a lifting assembly and a discharge platform, the lifting assembly and the discharge platform are both arranged on the machine table, the lifting assembly comprises a lifting motor, two vertical screws and a lifting platform, the lifting motor synchronously drives the two screws to synchronously rotate, nuts arranged on the two screws are respectively fixed with the lifting platform, the two lifting platforms synchronously lift at the same height, the lifting platform is used for supporting two ends of a central shaft of the coil, the discharge platform is used for placing the coil and unwinding the coil, the plane of the discharge platform is perpendicular to the screws, and when the lifting platform moves to be level with the height of the discharge platform, the coil can be horizontally moved from the lifting platform to the discharge platform.

3. The metal foil feeding device according to claim 2, wherein bearings are respectively arranged at two ends of the central shaft of the coil stock, a guide groove is arranged on the lifting platform, and the bearings are arranged in the guide groove and can roll in the guide groove; the discharging platform is provided with a straight groove corresponding to the guide groove, the tail end of the straight groove is provided with an upward-tilting arc-shaped groove, a rotatable opening and closing pressing block is arranged above the arc-shaped groove, the pressing block is used for pushing the bearing of the coil stock to the arc-shaped groove and clamping the bearing, and the movable end of the pressing block is controlled by a cylinder to move up and down.

4. The metal foil feeding apparatus according to claim 1, wherein the coil cutting mechanism comprises a base, an upper cutter and a lower cutter, the base is provided with an upper slide plate capable of moving up and down, the upper cutter is arranged on the upper slide plate, the upper part of the upper cutter is hinged with the upper slide plate, and the upper cutter can rotate up and down around the hinged part; the lower part of the upper cut-off knife is detachably and fixedly connected with the upper sliding plate, the upper cut-off knife is provided with a detachable upper knife head, and the upper knife head is embedded and fixed in the lower part of the upper cut-off knife.

5. The metal foil feeding apparatus according to claim 4, wherein the upper slide plate is provided with at least two horizontal cylinders, an output shaft of the horizontal cylinder is connected with the upper cutter, the horizontal cylinder retracts when the upper slide plate descends to cut so that the upper cutter and the lower cutter form vertical shearing, and the horizontal cylinder extends when the upper slide plate ascends so that the upper cutter is separated from the lower cutter.

6. The metal foil feeding device according to claim 5, wherein the upper sliding plate is provided with at least two positioning columns, the positioning columns are arranged on one side of the horizontal cylinder, and the axes of the positioning columns are collinear with the output shaft of the horizontal cylinder; when the output shaft of the horizontal cylinder retracts and drives the upper cutter to rotate to the maximum stroke, the positioning column is abutted against the upper cutter, and the upper cutter descends to form vertical shearing with the lower cutter.

7. The metal foil feeding apparatus according to claim 4, wherein said lower cutter has a lower blade, said web is passed through a top surface of said lower blade, said lower cutter has a transition surface flush with said top surface of said lower blade, said transition surface abuts against an opposite side of a cutting edge of said lower blade; the base is also provided with a pressing strip for pressing the coil stock, the pressing strip provides pressing force through an air cylinder, and the coil stock is pressed on the transition surface and the top surface of the lower cutter head through the pressing strip.

8. The metal foil feeding device according to any one of claims 1 to 7, wherein the receiving platform comprises a horizontal receiving plate capable of ascending and descending, a plurality of fixed top posts with the same height and a clamping assembly; when the horizontal material receiving plate rises to a position for receiving the coil materials, the ejection column is positioned below the horizontal material receiving plate, and the material clamping assembly is used for clamping the coil materials, pulling out the coil materials along a straight line and placing the cut coil materials on the horizontal material receiving plate; when the horizontal material receiving plate descends to a height lower than the top column, the top column is used for receiving a tray for placing the sheet materials.

9. The metal foil feeding device according to claim 8, wherein the clamping assembly comprises a clamping jaw, a horizontal lead screw and a vertical cylinder, the vertical cylinder is used for driving the clamping jaw to move up and down, and the horizontal lead screw is used for driving the vertical cylinder and the clamping jaw to move horizontally and linearly.

10. The metal foil feeding device according to claim 9, wherein when the horizontal material receiving plate is lifted to a position for receiving the coil, the vertical cylinder drives the clamping jaw to be lifted to a height higher than that of the horizontal material receiving plate, and when the clamping jaw pulls out the coil, a gap is reserved between the coil and the horizontal material receiving plate; after the coil stock is cut, the vertical cylinder drives the clamping jaw to descend so as to place the coil stock on the horizontal material receiving plate.

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