CN216711107U - Multifunctional die-cutting machine - Google Patents

Abstract

The utility model relates to a multifunctional die-cutting machine, comprising: the discharging device comprises a bearing assembly and an induction assembly; the bearing assembly comprises a bearing frame, a bearing disc and a hydraulic cylinder; the induction assembly comprises a support frame and a deviation rectifying sensor; the die cutting device is positioned at one end of the discharging device; the deviation correcting device is arranged on the die cutting device; the deviation correcting device comprises a conveyor belt component and a pushing component; the conveyor belt component comprises two frames, a conveyor belt and a limiting connecting rod; the pushing assembly comprises a fixed frame, a first moving plate, two cross-shaped moving platforms, a second moving plate and a cross-shaped guide rail pair. Above-mentioned multi-functional cross cutting machine, simple structure, convenient to use utilizes blowing device and deviation correcting device to form the second grade structure of rectifying, in the blowing of material and transfer process, can carry out many times adjustment to the position of material and correct, has improved the efficiency of rectifying greatly, avoids taking place the skew, guarantees cross cutting quality and product percent of pass.

Description

Multifunctional die-cutting machine

Technical Field

The utility model relates to the technical field of die cutting machines, in particular to a multifunctional die cutting machine.

Background

The die cutting machine is also called as a beer machine, a cutting machine and a numerical control punching machine, is mainly used for processing materials such as non-metallic materials, non-setting adhesive, double faced adhesive tapes and the like, applies certain pressure through a stamping plate by utilizing a steel knife, a hardware die and a steel wire, rolls and cuts the materials into a certain shape, and is important equipment for processing and molding after printing and packaging.

In the die cutting machine in the prior art, materials to be die-cut are generally conveyed to a die cutting assembly, due to reasons such as vibration, the materials on a feeding device are easy to deviate from the center in the conveying process, and when the materials are conveyed to the die cutting assembly, the materials deviate from a die cutting platform, so that the die cutting quality is low, and the product yield is low.

SUMMERY OF THE UTILITY MODEL

Based on the structure, the multifunctional die-cutting machine is simple in structure, convenient to use and provided with a two-stage deviation rectifying structure, the deviation of the material can be rectified twice, the conveying position of the material can be effectively rectified, the position deviation is avoided, and the die-cutting quality and the product percent of pass are ensured.

In order to realize the purpose of the utility model, the utility model adopts the following technical scheme:

a multi-function die cutting machine, comprising:

the discharging device comprises a bearing assembly and an induction assembly arranged on one side of the bearing assembly; the bearing assembly comprises a bearing frame, a bearing disc in sliding connection with the bearing frame, and a hydraulic cylinder arranged in the middle of the bearing frame; the cylinder body of the hydraulic cylinder is connected with the bearing frame, and the piston rod of the hydraulic cylinder is connected with the bearing disc; the induction assembly comprises a support frame arranged on one side of the bearing frame and a deviation rectifying sensor arranged on one side of the top of the support frame; the deviation rectifying sensor is used for driving the hydraulic cylinder;

the die cutting device is positioned at one end of the discharging device; and

the deviation correcting device is arranged on the die cutting device; the deviation correcting device comprises a conveyor belt component and pushing components arranged in the middle of two opposite ends of the conveyor belt component; the conveying belt component comprises two frames which are arranged at intervals, a conveying belt sleeved between the two frames and a limiting connecting rod for connecting the two frames; the pushing assembly comprises a fixed frame, a first moving plate which is slidably arranged on the top surface of the fixed frame, two cross-shaped moving platforms which are arranged between the fixed frame and the first moving plate, a second moving plate which is slidably arranged on the bottom surface of the fixed frame, and a cross-shaped guide rail pair which is arranged between the fixed frame and the second moving plate; the fixed frame is used for fixedly connecting two opposite ends of the die cutting device; the first moving plate and the second moving plate move synchronously, the first moving plate and the second moving plate are used for being installed in the frames, and the two cross-shaped moving platforms are used for driving the frames to deviate relative to the die cutting device.

Above-mentioned multi-functional cross cutting machine, simple structure, convenient to use utilizes blowing device and deviation correcting device to form the second grade structure of rectifying, in the blowing of material and transfer process, can carry out many times adjustment to the position of material and correct, has improved the efficiency of rectifying greatly, avoids taking place the skew, guarantees cross cutting quality and product percent of pass.

In one embodiment, the cross-shaped motion platform comprises a base, a first motion sliding block, a second motion sliding block and a linear motor, wherein the first motion sliding block is slidably mounted on the base; one end of the linear motor is connected with a first moving sliding block so as to drive the first moving sliding block to slide along the base; the motion direction of the first motion sliding block is consistent with the extension direction of the linear motor, and the motion direction of the first motion sliding block is perpendicular to the motion direction of the second motion sliding block.

In one embodiment, one of the cross motion platforms is installed at one end of the top surface of the fixed frame, and the other cross motion platform is installed at the other end of the top surface of the fixed frame; the extension directions of the linear motors of the two cross motion platforms are mutually perpendicular.

In one embodiment, the emptying device further comprises an emptying component arranged on one side of the bearing component and a feeding component arranged on the other side of the bearing component; the feeding assembly is positioned on one side of the induction assembly; the discharging assembly comprises supports arranged at two opposite ends of the bearing plate, a deflection seat hinged between the two supports, a material clamping claw slidably arranged on the deflection seat, a material passing roller connected to one side of the deflection seat and a deflection air cylinder arranged in the supports; one end of the deflection air cylinder is hinged to the support, the other end of the deflection air cylinder is hinged to the material passing roller, and the deflection air cylinder is used for driving the material passing roller and the deflection seat to deflect.

In one embodiment, the die cutting device comprises a machine table, a lower cutting die arranged at the top end of the machine table, a lifting cylinder arranged inside the lower cutting die, an upper cutting die connected to the top end of the lifting cylinder, and a cutter connected to one surface of the upper cutting die close to the lower cutting die; the lower cutting die and the upper cutting die are used for the conveyor belt and the materials to penetrate, and the lifting cylinder can drive the upper cutting die to be close to the lower cutting die.

In one embodiment, the multifunctional die cutting machine further comprises a visual positioning device mounted on the top of the die cutting device; the visual positioning device comprises a protective cover and a visual positioning assembly arranged on the top of the protective cover; the safety cover is used for covering the lower cutting die and the upper cutting die, grooves are formed in the bottom ends of two opposite sides of the safety cover respectively, and the conveyor belt and materials penetrate through the grooves and then are located between the lower cutting die and the upper cutting die.

In one embodiment, a plurality of observation grooves are arranged at the top of the upper cutting die at intervals; the visual positioning assembly comprises an installation plate arranged at the top end in the protective cover, X-axis transfer modules arranged at two opposite ends of the top surface of the installation plate, Y-axis transfer modules respectively connected with the X-axis transfer modules, Z-axis transfer modules arranged on the Y-axis transfer modules, and cameras arranged on the Z-axis transfer modules; the camera is used for corresponding to the observation groove.

Drawings

FIG. 1 is a schematic perspective view of a multi-function die cutting machine according to one embodiment of the present invention;

FIG. 2 is a perspective view of the multi-function die cutting machine shown in FIG. 1 from another perspective;

FIG. 3 is a schematic perspective view of a discharge device of the multi-function die cutting machine shown in FIG. 1;

FIG. 4 is a perspective view of another perspective view of the discharging device in the multi-functional die cutting machine shown in FIG. 3;

FIG. 5 is an exploded view of the discharging device of the multi-functional die cutting machine shown in FIG. 3;

FIG. 6 is an assembly view of the carrier tray and the discharging assembly of the multi-function die cutting machine shown in FIG. 5;

FIG. 7 is a perspective view of a feed assembly of the multi-function die cutting machine shown in FIG. 3;

FIG. 8 is a sectional view of a discharging device in the multi-function die cutting machine shown in FIG. 3;

FIG. 9 is a perspective view of a visual positioning device of the multi-function die cutting machine shown in FIG. 1;

FIG. 10 is an exploded view of the visual positioning mechanism of the multi-function die cutting machine shown in FIG. 9;

FIG. 11 is an internal assembly view of the visual positioning device of the multi-function die cutting machine shown in FIG. 9;

FIG. 12 is an exploded view of the visual positioning assembly of the multi-function die cutting machine shown in FIG. 10;

FIG. 13 is an exploded view of another perspective of the visual positioning assembly of the multi-function die cutting machine shown in FIG. 12;

FIG. 14 is an assembly view of a die cutting device and a deviation correcting device of the multi-functional die cutting machine shown in FIG. 1;

FIG. 15 is a schematic perspective view of a deviation rectification device of the multi-function die cutting machine shown in FIG. 14;

FIG. 16 is a perspective view of another perspective of the deviation rectification device of the multi-functional die cutting machine shown in FIG. 15;

FIG. 17 is a perspective view of a push assembly of the multi-function die cutting machine shown in FIG. 16;

FIG. 18 is an exploded view of a push assembly of the multi-function die cutting machine shown in FIG. 17;

FIG. 19 is an exploded view of another perspective of a push assembly of the multi-function die cutting machine shown in FIG. 18;

fig. 20 is a perspective view of the cross moving platform of the multi-function die cutting machine shown in fig. 18.

Reference is made to the accompanying drawings in which:

10-bearing component, 11-bearing frame, 12-bearing disc, 13-hydraulic cylinder, 14-hydraulic station, 15-bearing guide rail and 16-bearing slide block;

20-a feeding component, 21-a support, 210-a chute, 22-a deflection seat, 23-a material clamping claw, 231-a first push-pull cylinder, 232-a second push-pull cylinder, 233-a first chuck, 234-a second chuck, 235-a material clamping rotating motor, 24-a material passing roller and 25-a deflection cylinder;

30-a feeding component, 31-an electric cabinet, 32-a first fixed feeding roller, 33-a second fixed feeding roller, 34-a floating adjusting roller, 35-an adapter rod, 36-an electrostatic elimination rod and 37-a floating guide rail pair;

40-an induction component, 41-a support frame, 42-a deviation-rectifying sensor and 43-an induction port;

51-machine table, 52-lower cutting die, 53-lifting cylinder, 54-upper cutting die and 55-observation groove;

60-a conveyor belt assembly, 61-a frame, 62-a conveyor belt roller, 63-a horizontal adjusting roller, 64-a tension adjusting roller, 641-a tension guide rail pair, 642-a tension adjusting cylinder, 65-a dust removing roller, 66-a limiting connecting rod, 67-a power roller, 670-a conveyor belt driving motor, 68-a pressure plate and 69-a pressure cylinder;

70-pushing component, 71-fixing frame, 72-first moving plate, 73-cross motion platform, 731-base, 732-first motion slide block, 733-second motion slide block, 734-linear motor, 74-second moving plate, 75-cross guide rail pair and 76-protective cover;

81-protective box, 810-groove, 82-visual positioning component, 83-mounting plate, 830-through groove, 84-X-axis transfer module, 841-X-axis slide rail, 842-X-axis slide block, 843-X-axis driving motor, 844-lead screw, 85-Y-axis transfer module, 86-Z-axis transfer module, 861-fixed block, 862-free block, 863-adjusting handle and 87-camera;

91-a waste material pulling roller and 92-a waste material winding roller.

Detailed Description

To facilitate an understanding of the utility model, the utility model will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

Referring to fig. 1 to 20, a multi-functional die cutting machine according to an embodiment of the present invention includes a discharging device, a die cutting device at one end of the discharging device, a deviation rectifying device installed on the die cutting device, a visual positioning device installed on the top of the die cutting device, and a waste collecting device installed on the die cutting device and far away from the discharging device.

The discharging device comprises a bearing component 10, a discharging component 20 arranged on one side of the bearing component 10, a feeding component 30 arranged on the other side of the bearing component 10, and an induction component 40 arranged on one side of the bearing component 10, wherein the induction component 40 is positioned on one side of the feeding component 30.

The bearing assembly 10 comprises a bearing frame 11, a bearing disc 12 connected with the bearing frame 11 in a sliding manner, a hydraulic cylinder 13 arranged in the middle of the bearing frame 11, and a hydraulic station 14 arranged at one end of the bearing frame 11; the hydraulic station 14 is connected to the hydraulic cylinder 13 to provide a power source for the hydraulic cylinder 13. Wherein, one side of the carrier tray 12 is used for bearing and installing the emptying assembly 20, and the other side of the carrier tray 12 is used for bearing and installing the feeding assembly 30. The cylinder body of the hydraulic cylinder 13 is connected with the bearing frame 11, and the piston rod of the hydraulic cylinder 13 is connected with the bearing disc 12 so as to drive the bearing disc 12 and the bearing frame 11 to slide relatively.

As shown in fig. 5 and 6, a plurality of bearing guide rails 15 are respectively connected to two opposite ends of the top surface of the bearing frame 11, a plurality of bearing sliders 16 are respectively connected to two opposite ends of the bottom surface of the bearing disc 12, and the bearing sliders 16 and the bearing guide rails 15 are correspondingly matched one to one, so as to realize the sliding connection between the bearing disc 12 and the bearing frame 11.

The discharging assembly 20 comprises support seats 21 arranged at two opposite ends of the bearing plate 12, a deflection seat 22 hinged between the two support seats 21, a material clamping claw 23 arranged on the deflection seat 22 in a sliding manner, a material passing roller 24 connected to one side of the deflection seat 22, and a deflection cylinder 25 arranged in the support seats 21; one end of the deflection air cylinder 25 is hinged with the support 21, the other end of the deflection air cylinder 25 is hinged with the material passing roller 24, and the deflection air cylinder 25 can drive the material passing roller 24 and the deflection seat 22 to deflect.

Specifically, as shown in fig. 6, the inner side surface of the support 21 is provided with a sliding groove 210 arranged in an arc shape, the material passing roller 24 penetrates through the sliding groove 210 and then is hinged to the deflection cylinder 25, and the material passing roller 24 can be driven to deflect along the sliding groove 210 by the aid of the expansion and contraction of the deflection cylinder 25 in the using process, so that the deflection seat 22 is driven to deflect, and the material clamping claw 23 can conveniently grab the material roll close to the ground.

In this embodiment, as shown in fig. 4 and 5, the material clamping claw 23 includes a first push-pull cylinder 231 and a second push-pull cylinder 232 mounted in the middle of the swing seat 22, a first clamping head 233 slidably mounted on one end of the swing seat 22, a second clamping head 234 slidably mounted on the other end of the swing seat 22, and a material clamping rotating motor 235 mounted on one side of the second clamping head 234. One end of the first push-pull cylinder 231 is connected with the first chuck 233, one end of the second push-pull cylinder 232 is connected with the second chuck 234, and the first push-pull cylinder 231 and the second push-pull cylinder 232 can drive the first chuck 233 and the second chuck 234 to approach or move away from each other so as to grab the material roll.

The feeding assembly 30 comprises electric control boxes 31 arranged at two opposite ends of the bearing disc 12, a first fixed feeding roller 32 connected to one side of the tops of the two electric control boxes 31, a second fixed feeding roller 33 connected to the other side of the tops of the two electric control boxes 31, a floating adjusting roller 34 arranged between the two electric control boxes 31 in a lifting mode, adapter rods 35 arranged between the two electric control boxes 31 at intervals, and static eliminating rods 36 respectively connected with the adapter rods 35. Wherein, the first fixed feed roller 32 is close to the material passing roller 24, the second fixed feed roller 33 is far away from the material passing roller 24, and the floating adjusting roller 34 is positioned right below the position between the first fixed feed roller 32 and the second fixed feed roller 33. As shown in fig. 5 and 7, the adapter rod 35 is located between the material passing roller 24 and the first fixed feed roller 32. The two static elimination rods 36 are oppositely arranged, and the two static elimination rods 36 are used for material penetration to eliminate static of the material.

In this embodiment, the floating guide rail pairs 37 are respectively installed on the inner side of each electric cabinet 31, the moving direction of the floating guide rail pairs 37 is consistent with the vertical direction, and the two floating guide rail pairs 37 are respectively connected with the two opposite ends of the floating adjusting roller 34, so that the material is kept tight under the self-weight action of the floating adjusting roller 34, the tension of the material is further adjusted, and the material is conveniently conveyed.

The sensing assembly 40 comprises a supporting frame 41 arranged on one side of the bearing frame 11 and a deviation rectifying sensor 42 arranged on one side of the top of the supporting frame 41; the deviation rectifying sensor 42 is provided with an induction port 43, and the induction port 43 is used for the penetration of materials. The deviation-correcting sensor 42 is electrically connected with the hydraulic station 14 to drive the hydraulic cylinder 13 to work, and the deviation-correcting sensor 42 is positioned at one side of the second fixed feeding roller 33 to perform deviation-correcting detection on the material conveyed by the feeding assembly 30.

As shown in fig. 8, in actual operation, the material is discharged from the material clamping claw 23 and passes through the material passing roller 24, the material is inserted between the two static eliminating rods 36, after the static is eliminated, the material is inserted in the first fixed feeding roller 32, the floating adjusting roller 34 and the second fixed feeding roller 33 in sequence, and then the material is inserted in the deviation rectifying sensor 42 and finally fed into the die cutting device. In the process, if the deviation-correcting sensor 42 detects that the position of the material deviates, the deviation can be fed back to the hydraulic cylinder 13, and the hydraulic cylinder 13 drives the bearing plate 12 and the bearing frame 11 to slide relatively, so that the discharging assembly 20 and the feeding assembly 30 move transversely to correct the deviation.

The die cutting device includes a machine base 51, a lower cutting die 52 mounted on the top of the machine base 51, a lifting cylinder 53 mounted inside the lower cutting die 52, an upper cutting die 54 connected to the top of the lifting cylinder 53, and a cutter (not shown) connected to one surface of the upper cutting die 54 close to the lower cutting die 52. The lower cutting die 52 and the upper cutting die 54 are used for the belt and the material to penetrate through, and the lifting cylinder 53 can drive the upper cutting die 54 to be close to the lower cutting die 52, so that the cutter abuts against the lower cutting die 52 to cut the material.

Further, in the present embodiment, a plurality of observation grooves 55 are formed at intervals on the top of the upper cutting die 54, and the observation grooves 55 are used for positioning the visual positioning device.

The deviation correcting device comprises a conveyor belt assembly 60 and pushing assemblies 70 arranged in the middle of two opposite ends of the conveyor belt assembly 60. Wherein, the middle part of the conveyor belt assembly 60 is used for accommodating and installing the die cutting device, and the pushing assemblies 70 are also respectively connected to the two opposite ends of the die cutting device, so that the conveyor belt assembly 60 can be pushed to deviate to correct the deviation of the conveyed materials.

The conveyor belt assembly 60 includes two frames 61 arranged at intervals, a conveyor belt roller 62 mounted on the top of each frame 61, a horizontal adjusting roller 63 slidably mounted on the top of each frame 61, a tension adjusting roller 64 slidably mounted on the bottom of each frame 61, a dust removing roller 65 mounted on the bottom of each frame 61, a conveyor belt (not shown) sleeved between the two frames 61, and a limit link 66 connecting the two frames 61. Wherein, the horizontal adjusting roller 63 is positioned below the belt conveying roller 62, and the tension adjusting roller 64 is positioned above the dust removing roller 65; the conveyor belt is respectively provided with a conveyor belt roller 62, a horizontal adjusting roller 63, a tension adjusting roller 64 and a dust removing roller 65 in a penetrating way.

In this embodiment, the conveyor assembly 60 further includes a power roller 67 mounted on top of one of the frames 61, and a conveyor drive motor 670 mounted on one side of the frame 61. The power roller 67 is penetrated by the conveyor belt, and the conveyor belt driving motor 670 is connected with one end of the power roller 67 to drive the power roller 67 to rotate, so that the conveyor belt is driven to run.

In the present embodiment, a pushing assembly 70 is installed between the horizontal adjusting roller 63 and the tension adjusting roller 64, the horizontal adjusting roller 63 can perform a translational motion in the horizontal direction, and the tension adjusting roller 64 can perform a translational motion in the vertical direction. Specifically, opposite ends of the dancer roller 64 are slidably coupled to the inner surface of the frame 61 via a pair of tension guide rails 641, respectively. Furthermore, two opposite ends of the tension adjusting roller 64 are respectively connected with a tension adjusting cylinder 642, a cylinder body of the tension adjusting cylinder 642 is fixedly connected to the inner side surface of the frame 61, and a piston rod of the tension adjusting cylinder 642 is connected with the tension adjusting roller 64 to drive the tension adjusting roller 64 to vertically move along the tension guide rail pair 641, so as to achieve the effect of adjusting tension.

In the present embodiment, the length direction of the tension adjusting cylinder 642 coincides with the vertical direction.

Further, the conveyor belt assembly 60 further includes a plurality of press plates 68 slidably mounted on the top of each frame 11, and press cylinders 69 connected to opposite ends of each press plate 68. The material pressing plate 68 and the belt conveying roller 62 are used for the belt and the material to pass through, and the material pressing cylinders 69 are installed on two opposite sides of the frame 11. During operation, after the material is arranged between the belt conveying roller 62 and the material pressing plate 68 in a penetrating mode, the material pressing cylinder 69 drives the material pressing plate 68 to press down and abut against the material, so that the material is tightened, the die cutting device is convenient to cut, and the material cannot easily deviate when being cut.

The pushing assembly 70 comprises a fixed frame 71, a first moving plate 72 slidably mounted on the top surface of the fixed frame 71, two cross motion platforms 73 mounted between the fixed frame 71 and the first moving plate 72, a second moving plate 74 slidably mounted on the bottom surface of the fixed frame 71, a cross guide pair 75 mounted between the fixed frame 71 and the second moving plate 74, and a protective cover 76 connecting the first moving plate 72 and the second moving plate 74; the first moving plate 22 moves synchronously with the second moving plate 74; one cross-shaped moving platform 73 is installed at one end of the top surface of the fixed frame 71, the other cross-shaped moving platform 73 is installed at the other end of the top surface of the fixed frame 71, and the installation directions of the two cross-shaped moving platforms 73 are perpendicular to each other. The fixing frame 71 is used for fixedly connecting two opposite ends of the machine 51, and the frame 61 and the machine 51 are arranged at intervals. The first moving plate 72 and the second moving plate 74 are used for being installed in each frame 61, and the two cross-shaped moving platforms 73 are used for driving each frame 61 to generate certain offset relative to the machine table 51, so that the conveying position of the material can be effectively corrected, and the position offset is avoided.

As shown in fig. 17 to 20, the cross-shaped moving platform 73 includes a base 731, a first moving block 732 slidably mounted on the base 731, a second moving block 733 slidably mounted on the first moving block 732, and a linear motor 734 mounted on one end of the base 731; one end of the linear motor 734 is connected to the first moving slider 732 to drive the first moving slider 732 to slide along the base 731. The moving direction of the first moving block 732 is the same as the extending and retracting direction of the linear motor 734, and the moving direction of the first moving block 732 is perpendicular to the moving direction of the second moving block 733. In the present embodiment, the mounting directions of the two cross motion platforms 73 are perpendicular to each other, that is, the extension and contraction directions of the linear motors 734 of the two cross motion platforms 73 are perpendicular to each other, so that the first moving plate 72 and the second moving plate 74 can realize the movement in the X-axis direction and the Y-axis direction on the horizontal plane.

In the present embodiment, the cross rail pair 75 has two movement directions perpendicular to each other, so that the second moving plate 74 can move in the X-axis direction and the Y-axis direction of the horizontal plane in synchronization with the first moving plate 72.

Further, in this embodiment, the movement of the two pushing assemblies 70 located at the two opposite ends of the die cutting device may be synchronous or asynchronous, where asynchronous means that one pushing assembly 70 moves while the other pushing assembly 70 remains stationary, which can conveniently and effectively correct the conveying position of the material, avoid the occurrence of position deviation, and ensure the die cutting quality and efficiency. Meanwhile, under the limitation of the two limit connecting rods 66, the two frames 61 can be prevented from being excessively staggered, and the structural stability is ensured.

The multifunctional die-cutting machine disclosed by the utility model forms a two-stage deviation rectifying structure by utilizing the discharging device and the deviation rectifying device, the discharging device can perform first-stage deviation rectifying from the discharging of the materials, and the deviation rectifying device can perform second-stage deviation rectifying in the conveying process of the materials, so that the positions of the materials can be adjusted and corrected for multiple times, the deviation rectifying efficiency is greatly improved, the position deviation is avoided, and the die-cutting quality and the product percent of pass are ensured.

The visual positioning device comprises a protective box 81 and a visual positioning assembly 82 arranged on the top of the protective box 81. The protective box 81 is used for covering the lower cutting die 52 and the upper cutting die 54 of the die cutting device, the bottom ends of two opposite sides of the protective box 81 are respectively provided with a through groove 810, and the conveyor belt and the materials are positioned between the lower cutting die 52 and the upper cutting die 54 for cutting after penetrating through the through grooves 810.

The visual positioning assembly 82 comprises an installation plate 83 arranged at the top end inside the protective box 81, X-axis transfer modules 84 arranged at two opposite ends of the top surface of the installation plate 83, Y-axis transfer modules 85 respectively connected with the X-axis transfer modules 84, Z-axis transfer modules 86 arranged on the Y-axis transfer modules 85, and cameras 87 arranged on the Z-axis transfer modules 86; the camera 87 is used for corresponding to the observation groove 55, that is, the camera 87 captures the marked points of the materials through the observation groove 55 to determine whether the position of the materials is shifted.

In this embodiment, the opposite ends of the mounting plate 83 are respectively connected with through slots 830, and the through slots 830 are used for the components of the X-axis transfer module 84 to penetrate through.

In this embodiment, the X-axis transfer module 84 includes an X-axis slide rail 841 connected to one end of the top surface of the mounting plate 83, an X-axis slider 842 slidably connected to the X-axis slide rail 841, an X-axis driving motor 843 mounted to one end of the top surface of the mounting plate 83, and a lead screw 844 connected to the X-axis driving motor 843; an internal threaded hole is formed in the middle of the X-axis slider 842 and is matched with the screw 844, so that the X-axis slider 842 is connected with the screw 844 in a sliding manner. When the X-axis driving motor 843 drives the lead screw 844 to rotate, the X-axis slider 842 can be driven to slide along the X-axis slide rail 841. The X-axis slider 842 is connected with the Y-axis transfer module 85 after penetrating the through groove 830.

In this embodiment, the Y-axis transfer module 85 is an electric linear sliding table.

In this embodiment, the Z-axis transfer module 86 includes a fixed block 861 connected to the Y-axis transfer module 85, a free block 862 slidably connected to the fixed block 861, and an adjusting handle 863 connected to the free block 862 after passing through the fixed block 861; the fixing block 861 is clamped between the adjusting handle 863 and the free block 862, and the distance between the adjusting handle 863 and the free block 862 can be changed by rotating the adjusting handle 863, so that the free block 862 can conveniently slide on the fixing block 861 to change the height of the free block 862. The free block 862 is used to carry the mounting camera 87, and the direction of movement of the free block 862 coincides with the vertical direction.

Referring to fig. 1 and fig. 2 again, the waste collecting device includes a waste pulling roller 91 installed on one side of the lower cutting die 52, and a waste winding roller 92 installed on one side of the waste collecting power roller 91 far from the lower cutting die 52. After the material is cut by passing through the space between the lower cutting die 52 and the upper cutting die 45, the cut finished product is sent to the next process along with the conveyor belt, and the waste material pulling roller 91 pulls the residual waste material and winds the waste material on the waste material winding roller 92.

Above-mentioned multi-functional cross cutting machine, simple structure, convenient to use utilizes blowing device and deviation correcting device to form the second grade structure of rectifying, in the blowing of material and transfer process, can carry out many times adjustment to the position of material and correct, has improved the efficiency of rectifying greatly, avoids taking place the skew, guarantees cross cutting quality and product percent of pass.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent should be subject to the appended claims.

Claims (7)

1. A multifunctional die cutting machine, comprising:

the discharging device comprises a bearing assembly and an induction assembly arranged on one side of the bearing assembly; the bearing assembly comprises a bearing frame, a bearing disc in sliding connection with the bearing frame, and a hydraulic cylinder arranged in the middle of the bearing frame; the cylinder body of the hydraulic cylinder is connected with the bearing frame, and the piston rod of the hydraulic cylinder is connected with the bearing disc; the induction assembly comprises a support frame arranged on one side of the bearing frame and a deviation rectifying sensor arranged on one side of the top of the support frame; the deviation rectifying sensor is used for driving the hydraulic cylinder;

the die cutting device is positioned at one end of the discharging device; and

the deviation correcting device is arranged on the die cutting device; the deviation correcting device comprises a conveyor belt component and pushing components arranged in the middle of two opposite ends of the conveyor belt component; the conveying belt component comprises two frames which are arranged at intervals, a conveying belt sleeved between the two frames and a limiting connecting rod for connecting the two frames; the pushing assembly comprises a fixed frame, a first moving plate which is slidably arranged on the top surface of the fixed frame, two cross-shaped moving platforms which are arranged between the fixed frame and the first moving plate, a second moving plate which is slidably arranged on the bottom surface of the fixed frame, and a cross-shaped guide rail pair which is arranged between the fixed frame and the second moving plate; the fixed frame is used for fixedly connecting two opposite ends of the die cutting device; the first moving plate and the second moving plate move synchronously, the first moving plate and the second moving plate are used for being installed in the frames, and the two cross-shaped moving platforms are used for driving the frames to deviate relative to the die cutting device.

2. The multi-function die cutting machine of claim 1, wherein the cross motion platform includes a base, a first motion block slidably mounted on the base, a second motion block slidably mounted on the first motion block, and a linear motor mounted at one end of the base; one end of the linear motor is connected with a first moving sliding block so as to drive the first moving sliding block to slide along the base; the motion direction of the first motion sliding block is consistent with the extension direction of the linear motor, and the motion direction of the first motion sliding block is perpendicular to the motion direction of the second motion sliding block.

3. The multi-function die cutting machine of claim 2, wherein one of said cross motion platforms is mounted to one end of said stationary frame top surface and the other of said cross motion platforms is mounted to the other end of said stationary frame top surface; the extension directions of the linear motors of the two cross motion platforms are mutually perpendicular.

4. The multifunctional die cutting machine according to claim 1, wherein the discharging device further comprises a discharging assembly mounted on one side of the bearing assembly, and a feeding assembly mounted on the other side of the bearing assembly; the feeding assembly is positioned on one side of the induction assembly; the discharging assembly comprises supports arranged at two opposite ends of the bearing plate, a deflection seat hinged between the two supports, a material clamping claw slidably arranged on the deflection seat, a material passing roller connected to one side of the deflection seat and a deflection air cylinder arranged in the supports; one end of the deflection air cylinder is hinged to the support, the other end of the deflection air cylinder is hinged to the material passing roller, and the deflection air cylinder is used for driving the material passing roller and the deflection seat to deflect.

5. The multifunctional die cutting machine according to claim 1, wherein the die cutting device comprises a machine table, a lower cutting die arranged at the top end of the machine table, a lifting cylinder arranged inside the lower cutting die, an upper cutting die connected to the top end of the lifting cylinder, and a cutter connected to one surface of the upper cutting die close to the lower cutting die; the lower cutting die and the upper cutting die are used for the conveyor belt and the materials to penetrate, and the lifting cylinder can drive the upper cutting die to be close to the lower cutting die.

6. The multi-function die cutting machine of claim 5, further comprising a vision positioning device mounted on top of the die cutting device; the visual positioning device comprises a protective cover and a visual positioning assembly arranged on the top of the protective cover; the safety cover is used for covering the lower cutting die and the upper cutting die, grooves are formed in the bottom ends of two opposite sides of the safety cover respectively, and the conveyor belt and materials penetrate through the grooves and then are located between the lower cutting die and the upper cutting die.

7. The multi-function die cutting machine of claim 6, wherein a plurality of viewing slots are spaced apart in a top portion of the upper die; the visual positioning assembly comprises an installation plate arranged at the top end in the protective cover, X-axis transfer modules arranged at two opposite ends of the top surface of the installation plate, Y-axis transfer modules respectively connected with the X-axis transfer modules, Z-axis transfer modules arranged on the Y-axis transfer modules, and cameras arranged on the Z-axis transfer modules; the camera is used for corresponding to the observation groove.

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