CN115488215A - Die-cutting rule production equipment integrating multiple specifications - Google Patents

Abstract

The invention discloses a production device integrating multiple specifications of die-cutting rule, comprising: the cutter head assembly is used for placing a cutter material, the feeding assembly, the bridge position punching assembly, the material receiving tray assembly and the workbench; the feeding assembly and the feeding assembly are used for feeding, the bridge position punching assembly is used for carrying out bridge position punching on the cutter materials, and the material receiving tray assembly is used for collecting the punched cutter materials. Design more than adopting, through setting up the dish of placing of a plurality of different specifications, realize placing the sword material of multiple specification simultaneously, and it is corresponding with the feeding subassembly to place the dish through translation mechanism control correspondence, realize the sword material loading of predetermineeing the specification, save frequent reloading step, simultaneously through setting up first mould and second mould, realize the increase of die-cut scope, realize the selectivity of mould through die-cut briquetting, lifting means's use convenience, moreover, the steam generator is compact in structure, and reasonable design, small in size, effectual lifting means's application range, promote the manufacturing efficiency of product.

Description

Die-cutting rule production equipment integrating multiple specifications

Technical Field

The invention relates to the technical field of die-cutting cutters, in particular to a multi-specification die-cutting cutter integrated production device.

Background

The die-cutting rule is also called a beer knife or an indentation knife; refers to a sheet material made of steel with a cutting edge at the top end and provided with a die-cut plate in rows. The existing production equipment of the die-cutting rule also adopts an automatic feeding mode, and the feeding mode uses a feeding roller shaft to drive the material to move; a plurality of specifications are usually set simultaneously when a client sets a sheet, however, the existing die-cutting rule feeding assembly can only be used for placing materials with a single specification, so that materials with other specifications are frequently replaced in the production process, the working efficiency is affected, and the die-cutting rule is placed on the die-cutting plate when the die-cutting rule feeding assembly is used, so that a groove with a preset shape can be cut on the die-cutting plate through laser according to requirements for placing the die-cutting rule, in order to prevent the die-cutting plate from being completely disconnected with the die-cutting plate and falling off in the cutting range when the die-cutting plate is subjected to laser cutting, intermittent cutting is usually carried out according to a preset length during cutting, so that the part in the cutting range is ensured to be connected with the die-cutting plate and prevented from falling off, the connected part is called as a die-cutting plate gap bridge, and simultaneously, in order to enable the die-cutting rule to be matched with the groove, a bridge hole matched with the die-cutting plate gap bridge needs to be formed at the position corresponding to the die-cutting rule, and the die-cutting rule gap bridge can also enable the die-cutting rule to be prevented from moving when the die-cutting rule is arranged in the groove; the die-cutting rule gap bridge is usually opened by using a die for die cutting, when die cutting is carried out, the specification of the die-cutting board gap bridge is not uniform and is determined along with the size of a template, so that the die-cutting equipment is required to be provided with the dies with a plurality of specifications, in the prior art, the die-cutting equipment is limited by space and structure, the die-cutting equipment is only provided with a group of dies, and the group of dies is provided with 3-5 dies with different specifications, but the application of the die-cutting rule is wide, the specification of the group of dies cannot meet the requirement, so that the die-cutting equipment or the die of the die needs to be replaced when other specifications are required, and the production efficiency is influenced.

Therefore, it is desirable to design a die-cutting rule production apparatus with multiple specifications to overcome the disadvantages of the prior art.

Disclosure of Invention

The technical scheme adopted by the invention to achieve the technical purpose is as follows: the utility model provides an collect many specifications die-cutting rule production facility which characterized in that includes: the device comprises a cutter head assembly, a feeding assembly, a bridge position punching assembly, a material receiving tray assembly and a workbench; the cutter head assembly is positioned on one side of the workbench, the receiving tray assembly is positioned on one side of the workbench opposite to the cutter head assembly, the feeding assembly and the bridge punching assembly are sequentially arranged on the workbench, the feeding assembly is positioned corresponding to the cutter head assembly, the bridge punching assembly corresponds to the receiving tray assembly, a plurality of placing discs with different sizes are arranged on the cutter head assembly and used for placing cutters, the placing discs can move along the width direction of the workbench, a plurality of collecting grooves which are matched with the placing discs one by one are arranged on the receiving tray assembly, and the receiving tray assembly can move along the width direction of the workbench; the feeding assembly is used for pulling out and delivering to the knife material in the cutter head assembly in the feeding assembly, the feeding assembly is used for delivering the knife material that the feeding assembly carried to in the die-cut subassembly of bridge position, the die-cut subassembly of bridge position includes: the punching mechanism is characterized by comprising a first die, a second die and a punching mechanism, wherein a plurality of cutting dies with different sizes are respectively arranged on the first die and the second die, the first die and the second die are arranged at the bottom of the punching mechanism side by side, a punching pressing block is arranged in the punching mechanism in a sliding manner, and the punching mechanism selects one of the first die and the second die to drive punching through the punching pressing block.

In a preferred embodiment, the cutterhead assembly includes: a frame, a translation mechanism; translation mechanism locates the top of frame, the last blade disc base that is connected with of translation mechanism, place the dish set up side by side in on the blade disc base, translation mechanism is used for driving the blade disc base removes along predetermineeing the direction.

In a preferred embodiment, each placing disc is internally provided with a plurality of material blocking shafts, the material blocking shafts are arranged in the placing discs in a semicircular shape, each material blocking shaft is rotatably provided with a roller, the top of each placing disc is fixedly provided with a guide block which is matched with the top of the placing disc, the guide blocks are horizontally arranged, each guide block is further provided with a knife pressing cylinder for pressing a knife material at a preset stage, and the middle of each guide block is provided with a through discharge hole for outputting the knife material.

In a preferred embodiment, the feeding assembly is in transmission connection with the feeding assembly, and the feeding assembly comprises: the feeding installation base is internally fixed at the bottom of the feeding installation base and provided with a feeding lower roller, a feeding upper roller is arranged above the feeding installation base in a sliding mode, the feeding lower roller is opposite to the feeding upper roller, and the feeding upper roller can move towards the direction of the feeding lower roller.

In a preferred embodiment, the feed assembly comprises: the feeding device comprises a feeding mounting base, wherein a feeding lower roller is fixedly arranged in the bottom of the feeding mounting base, a feeding upper roller is arranged above the feeding mounting base in a sliding mode and is opposite to the feeding lower roller, the feeding upper roller can move towards the direction of the feeding lower roller, the feeding lower roller is connected with a feeding motor, and the feeding lower roller is in transmission connection with the feeding lower roller.

In a preferred embodiment, a feeding and knife-passing mechanism is further disposed between the feeding assembly and the feeding assembly, and the feeding and knife-passing mechanism includes: feeding through a cutter bearing, feeding through a cutter mounting seat and feeding through a cutter pressing device; the feeding cutter shaft bearing is provided with two pairs of feeding cutter shaft bearings which are respectively arranged on two sides of the feeding cutter shaft bearing mounting seat, the feeding cutter pressing device is positioned between the two pairs of feeding cutter shaft bearings, each pair of feeding cutter shaft bearings are arranged at intervals, the middle part of the feeding cutter pressing device is provided with a feeding cutter pressing groove, and the cutter pressing groove corresponds to the interval between each pair of feeding cutter shaft bearings.

In a preferred embodiment, a feeding and knife passing mechanism is further arranged between the feeding assembly and the bridge position punching assembly, and the feeding and knife passing mechanism comprises: a feeding cutter-passing mounting seat, a feeding cutter-passing bearing and a feeding cutter presser; the feeding cutter passing shaft bearings are provided with two pairs and are respectively arranged on two sides of the feeding cutter passing mounting seat, the feeding cutter pressing device is positioned between the two pairs of feeding cutter passing shaft bearings, each pair of feeding cutter passing shaft bearings are arranged at intervals, the middle part of the feeding cutter pressing device is provided with a feeding cutter pressing groove, and the cutter pressing groove corresponds to each pair of feeding cutter passing shaft bearings at intervals.

In a preferred embodiment, the bridge punch assembly further comprises: the bridge position base, it is equipped with bridge position slip subassembly to slide on the bridge position base, the one end of bridge position base is equipped with the mould mounting panel, the one end of mould mounting panel is equipped with the position of placing that two intervals set up, first mould with the second mould with correspond place the position and can dismantle the connection, die-cutting mechanism locates the middle part of bridge position base, the one end of placing the position is equipped with the fixture block, the bridge position base is equipped with place the one end lateral wall of position and still install guide bearing.

In a preferred embodiment, the first mold comprises: the device comprises a first base, a first guide plate and a first connecting piece; the first base is arranged in one of the placing positions, the first guide plate is arranged above the first base, a plurality of penetrating guide holes are formed in the first guide plate, the first connecting piece is positioned above the first guide plate, a plurality of cutting dies are arranged on the first connecting piece at intervals, the first guide holes are matched with the corresponding cutting dies, a plurality of first back plates are further paved on the first base, first through holes matched with the cutting dies one by one are formed in the first back plates, and the first guide plate and the first back plates are arranged at intervals; the cutting die is characterized in that horizontally extending protruding portions are arranged on two sides of the top of the first connecting piece respectively, a first sliding groove is formed in the middle of the first connecting piece, first limiting grooves are formed in two side walls of the first sliding groove respectively, a first limiting column is arranged at the top of the cutting die in a penetrating mode, the first limiting column is matched with the first limiting grooves, and a first clamping groove is formed in one end of the first base.

In a preferred embodiment, the die cutting mechanism comprises: the punching base is arranged on the bridge position base in a crossing mode, the first module and the second module are located in the punching base, a motor mounting seat is fixedly connected above the punching base, a punching motor is fixedly connected in the motor mounting seat, the output end of the punching motor penetrates out of the motor mounting seat and is connected with an eccentric shaft, a punching sliding plate is sleeved on the outer side of the eccentric shaft and is connected with the motor mounting seat in a sliding mode, the bottom end of the punching sliding plate is connected with a punching pressing seat, the punching pressing seat is provided with two avoidance positions for placing the first die and the second die, a placing hole is formed in one end, connected with the eccentric shaft, of the punching sliding plate, the eccentric shaft is located in the placing hole, the diameter of the placing hole is larger than that of the eccentric shaft, inserts are respectively arranged at two vertical ends of the placing hole and abut against the eccentric shaft, and the eccentric shaft can horizontally slide in the placing hole; the die-cut pressure seat is internally provided with two transposition chutes which run through the avoidance, the top of the transposition chute is provided with a die-cut limiting groove, the die-cut pressing block is arranged in the transposition chute in a sliding manner, the top of the die-cut pressing block is provided with a limiting lug, the limiting lug is matched with the die-cut limiting groove, one side of the die-cut pressure seat is also provided with a transposition cylinder, and the output end of the transposition cylinder is fixedly connected with the die-cut pressing block.

In a preferred embodiment, a marking assembly is further arranged between the feeding assembly and the bridge position punching assembly and used for printing preset patterns and/or characters on the surface of the cutter.

The invention has the beneficial effects that: through set up the dish of placing of a plurality of different specifications on blade disc assembly, the blade disc assembly that makes can place the sword material of multiple specification simultaneously, and it is corresponding with the feeding subassembly to place the dish through translation mechanism control correspondence, realize the sword material loading of predetermineeing the specification, save frequent reloading step, simultaneously through setting up first mould and second mould in the die-cut subassembly in bridge position, realize the increase of die-cut scope, realize the alternative of mould through die-cut briquetting, lifting means's use convenience, moreover, the steam generator is compact in structure, and reasonable in design, small, effectual lifting means's application range, lifting means's practicality, promote the manufacturing efficiency of product, and can select the module of different functions according to the demand, lifting means's pluralism.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the construction of the cutterhead assembly of the present invention;

FIG. 3 is an exploded view of the cutterhead assembly of the present invention;

FIG. 4 is a schematic view of the feeding assembly and the feeding assembly of the present invention;

FIG. 5 is a schematic structural view of the feed through knife mechanism of the present invention;

FIG. 6 is a schematic structural view of a feed-through mechanism of the present invention;

FIG. 7 is a schematic view of the bridge punch assembly of the present invention;

FIG. 8 is a schematic structural diagram of a bridge site base according to the present invention;

FIG. 9 is a schematic view of the die cutting mechanism of the present invention;

FIG. 10 is a schematic view of the die-cutting press base according to the present invention;

FIG. 11 is a schematic plan view of the die cutting mechanism of the present invention;

fig. 12 is an exploded view of a first mold of the present invention.

In the figure:

10. a work table;

20. a cutter head assembly; 21. placing a tray; 22. a frame; 23. a translation mechanism; 24. a cutter head base; 25. a material blocking shaft; 26. a roller; 27. a guide block; 28. a discharge port; 29. a cutter pressing cylinder;

30. a feed assembly; 31. a feed mounting base; 32. feeding a lower roller; 33. feeding and feeding the materials to an upper roller;

40. a feeding assembly; 41. a feeding mounting base; 42. feeding a lower roller; 43. feeding and feeding the materials to an upper roller; 44. a feeding motor;

50. a feeding and knife-passing mechanism; 51. feeding and passing through a cutter mounting seat; 52. a feed knife presser; 53. feeding the materials through a cutter bearing; 54. a feeding cutter pressing groove;

60. a feeding and knife passing mechanism; 61. a feeding cutter mounting seat; 62. a feeding knife presser; 63. feeding and passing through a cutter bearing; 64. and feeding cutter pressing grooves.

70. A bridge position punching component; 71. a punching mechanism; 711. punching a base; 712. a motor mounting seat; 713. punching a motor; 714. an eccentric shaft; 715. punching a sliding plate; 716. punching and pressing the base; 717. avoidance positions; 718. placing holes; 719. an insert; 720. a transposition chute; 721. punching a limit groove; 722. a limiting bump; 723. a transposition air cylinder; 73. a bridge site base; 74. a bridge sliding assembly; 75. a mold mounting plate; 751. placing a bit; 752. a clamping block; 753. a guide bearing; 76. punching and pressing blocks;

80. a first mold; 81. a first base; 811. a first card slot; 82. a first guide plate; 821. a guide hole; 83. a first connecting member; 831. cutting the die; 832. a projection; 833. a first chute; 834. a first limit groove; 835. a first limit post; 84. a first back plate; 841. a first perforation;

90. a second mold;

100. a material receiving tray assembly; 110. and (7) collecting the tank.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, as those skilled in the art will recognize without departing from the spirit and scope of the present invention.

As shown in fig. 1, the present invention provides a multi-specification mold cutter production apparatus, which is characterized by comprising: the device comprises a cutter head assembly 20, a feeding assembly 30, a feeding assembly 40, a bridge position punching assembly 70, a material receiving tray assembly 100 and a workbench 10; the cutter head assembly 20 is located on one side of the workbench 10, the material receiving tray assembly 100 is located on one side of the workbench 10 opposite to the cutter head assembly 20, the feeding assembly 30, the feeding assembly 40 and the bridge punching assembly 70 are sequentially arranged on the workbench 10, the feeding assembly 40 is located corresponding to the cutter head assembly 20, the bridge punching assembly 70 corresponds to the material receiving tray assembly 100, a plurality of placing discs 21 with different sizes are arranged on the cutter head assembly 20 and used for placing the knife materials, the placing discs 21 can move in the width direction of the workbench 10, a plurality of collecting grooves 110 which are matched with the placing discs 21 one by one are arranged on the material receiving tray assembly 100, the material receiving tray assembly 100 can move in the width direction of the workbench 10, and the material receiving tray assembly 100 moves along with the cutter head assembly 20; the feeding assembly 30 is used for drawing out and sending the knife materials in the cutter head assembly 20 into the feeding assembly 40, the feeding assembly 40 is used for sending the knife materials conveyed by the feeding assembly 30 into the bridge position punching assembly 70, and the bridge position punching assembly 70 comprises: first mould 80 and second mould 90 and die-cut mechanism 71, first mould 80 with install a plurality of not unidimensional cutting die 831 on the second mould 90 respectively, first mould 80 with second mould 90 locates side by side the bottom of die-cut mechanism 71, it is equipped with die-cut briquetting 76 to slide in the die-cut mechanism 71, die-cut mechanism 71 passes through die-cut briquetting 76 in one of first mould 80 with in the second mould 90 selects one to drive die-cut.

Specifically, a plurality of knife materials with different specifications are placed in corresponding placing discs 21, when a knife with a certain specification needs to be manufactured, the cutter disc assembly 20 moves, so that the placing disc 21 with a certain specification needs to correspond to the feeding assembly 30, the end part of the knife material is placed in the feeding assembly 30, the feeding assembly 30 pulls the knife material to move towards the feeding assembly 40, the feeding assembly 40 pulls the knife material to move towards the bridge punching assembly 70, after the bridge punching assembly 70 punches the knife material, the knife material is pushed out of the bridge punching assembly 70 through the feeding assembly 40 and enters the receiving tray assembly 100, wherein the receiving tray assembly 100 is provided with a plurality of collecting grooves 110 which correspond to the placing discs 21 one by one, and the receiving tray assembly 100 can also move, so that the collecting grooves 110 correspond to the placing discs 21 with the same specification all the time; wherein the bridge site punch assembly 70 comprises: the cutting device comprises a first die 80, a second die 90 and a punching mechanism 71, wherein the first die 80 and the second die 90 are respectively connected with the punching mechanism 71, the first die 80 and the second die 90 are driven by the punching mechanism 71 to move, and further, cutting is carried out on a cutter material, wherein the first die 80 and the second die 90 are respectively provided with cutter dies 831 with different specifications, a punching press block 76 is further arranged in the punching mechanism 71 in a sliding manner, the punching mechanism 71 selects one synchronous driving motion from the first die 80 and the second die 90 through the punching press block 76, so that the corresponding cutter die 831 carries out bridge position punching on the cutter material, and after the punching is finished, a feeding assembly 40 forwards conveys the subsequent non-punched cutter material, so that the part which is finished is pushed out of a bridge position punching assembly 70 and enters a collecting disc corresponding to the bridge position punching assembly 70.

Further, as shown in fig. 2 to 3, in the present embodiment, the cutterhead assembly 20 includes: a frame 22, a translation mechanism 23; translation mechanism 23 is located the top of frame 22, be connected with cutter head base 24 on translation mechanism 23, place a set 21 set up side by side in on the cutter head base 24, translation mechanism 23 is used for driving cutter head base 24 is along predetermineeing the direction removal, and is concrete, and translation mechanism 23 adopts the common screw rod mechanism in market, so do not describe here, and cutter head base 24 is connected with translation mechanism 23, and a plurality of sets 21 of placing are placed side by side on cutter head base 24, drive cutter head base 24 when translation mechanism 23 moves to drive and place a set 21 and remove, be convenient for make one of them place a set 21 corresponding with feeding subassembly 30 to carry out the output of sword material.

Further, in this embodiment, each of the placing trays 21 is provided with a plurality of material blocking shafts 25, the material blocking shafts 25 are disposed in the placing trays 21 in a semicircular shape, each of the material blocking shafts 25 is rotatably provided with a roller 26, the top of the placing tray 21 is fixedly provided with a guide block 27 which is adapted to the top, the guide block 27 is horizontally disposed, the guide block 27 is further provided with a knife pressing cylinder 29 for pressing the knife material at a preset stage, the middle of the guide block 27 is provided with a through discharge port 28 for outputting the knife material, specifically, the material blocking shafts 25 are disposed in the bottom of the placing tray 21 in a semicircular shape, when the knife material roll is placed in the placing tray 21, the knife material is supported by the material blocking shafts 25, and meanwhile, through the structural design of the semicircular material roll, the knife material is placed and separated from the placing tray 21 when the knife material is output by the feeding assembly 30; in order to avoid that the rotating form of the knife material coil during output rubs with the material blocking shaft 25 to cause scraping of the knife material, a roller 26 is arranged in the middle of the material blocking shaft 25, and when the knife material rotates, the roller 26 is driven to rotate, so that the friction between the knife material and the material blocking shaft 25 is reduced, it needs to be explained that the roller 26 can be preferably made of a colloid material, and the friction force is further reduced; for avoiding the skew about the sword material when exporting, be equipped with guide block 27 on the top of placing dish 21, discharge gate 28 has been seted up at the middle part of this guide block 27, this discharge gate 28 and sword material adaptation, thereby make the sword material can pass guide block 27, restrict the sword material when exporting through guide block 27, the phenomenon of emergence skew, be the winding form because of the whole sword material that is, for avoiding when feeding subassembly 30 does not move, receive the influence sword material of winding force and withdraw by oneself, be equipped with pressing sword cylinder 29 on guide block 27, restrict the sword material through the pressing sword, avoid withdrawing.

Further, as shown in fig. 4, in the present embodiment, the feeding assembly 30 is in transmission connection with the feeding assembly 40, and the feeding assembly 30 includes: feeding installation base 31, the bottom internal fixation of feeding installation base 31 is equipped with feeding running roller 32 down, the top of feeding installation base 31 slides and is equipped with feeding top roller 33, feeding bottom roller 32 with feeding top roller 33 is relative, feeding top roller 33 can move towards feeding bottom roller 32 place direction removes, and is specific, feeding subassembly 30 and the transmission of pay-off subassembly 40 are connected, makes both when moving, can synchronous operation, avoids appearing one fast slow condition, influences the transport of running roller, wherein feeding subassembly 30 includes, feeding installation base 31, this feeding installation base 31's fixed feeding bottom roller 32 that is equipped with in bottom, slide at feeding installation base 31's top and be equipped with feeding top roller 33, wherein feeding top roller 33 passes through the mode drive of cylinder, messenger's feeding top roller 33 can move towards feeding bottom roller 32 place direction, reduce the spacing distance between feeding top roller 33 and the feeding bottom roller 32, thereby be convenient for the different thickness's of adaptation running roller 33 and feeding down through the extrusion between running roller 32 simultaneously, drive the running roller.

Further, as shown in fig. 4, in the present embodiment, the feeding assembly 40 includes: the feeding and mounting base 41 is provided with a feeding lower roller 42 fixed in the bottom of the feeding and mounting base 41, an upper feeding roller 43 is arranged above the feeding and mounting base 41 in a sliding manner, the upper feeding roller 43 is opposite to the feeding lower roller 42, the upper feeding roller 43 can move towards the direction of the feeding lower roller 42, the feeding lower roller 42 is connected with a feeding motor 44, the feeding lower roller 32 is in transmission connection with the feeding lower roller 42, specifically, the feeding lower roller 42 is fixed in the bottom of the feeding and mounting base 41, the upper feeding roller 43 is arranged at the top of the feeding and mounting base 41 in a sliding manner, the upper feeding roller 43 is driven in an air cylinder manner, so that the upper feeding roller 43 can move towards the direction of the feeding lower roller 42, the spacing distance between the upper feeding roller 43 and the feeding lower roller 42 is reduced, the upper feeding roller 43 and the feeding lower roller 42 are conveniently adapted to knife materials with different thicknesses, one end of the feeding lower roller 42 is connected with the feeding motor 44, the feeding lower roller 42 is driven to rotate by the feeding motor 44, and the feeding lower roller 42 is driven to rotate by the feeding upper feeding roller 43 and the feeding lower roller 42 when the feeding roller is rotated, and the feeding lower roller 32 is driven, and the feeding lower roller is connected with the feeding roller 42.

Further, as shown in fig. 5, in this embodiment, a feeding and knife passing mechanism 50 is further disposed between the feeding assembly 30 and the feeding assembly 40, and the feeding and knife passing mechanism 50 includes: a feeding cutter bearing 53, a feeding cutter mounting seat 51 and a feeding cutter pressing device 52; the feeding cutter passing shaft bearings 53 are provided with two pairs and are respectively arranged on two sides of the feeding cutter passing mounting seat 51, the feeding cutter pressing device 52 is positioned between the two pairs of feeding cutter passing shaft bearings 53, each pair of feeding cutter passing shaft bearings 53 are arranged at intervals, the middle part of the feeding cutter pressing device 52 is provided with a feeding cutter pressing groove 54, the cutter pressing groove corresponds to the interval between each pair of feeding cutter passing shaft bearings 53, specifically, a feeding cutter passing mechanism 50 is further arranged between the feeding assembly 30 and the feeding assembly 40, and the feeding cutter passing mechanism 50 comprises: the sword mount pad 51 is crossed in the feeding, it crosses arbor to hold 53 to be equipped with a pair of feeding respectively on the both sides of sword mount pad 51 is crossed in the feeding, when the sword material is pulled from placing a set 21 and is pulled out through the traction of feeding subassembly 30, get into between the feeding and cross arbor and hold 53, cross arbor and hold 53 through the feeding, support the sword material, make the horizontal feeding of sword material, feeding knife presser 52 is used for crossing arbor and hold 53 through the feeding at the sword material, flatten the sword material, avoid leading to the perk of rear end because of the extrusion of front end, so that the unable smooth transport of sword material.

Further, as shown in fig. 6, in this embodiment, a feeding and knife passing mechanism 60 is further disposed between the feeding assembly 40 and the bridge position punching assembly 70, and the feeding and knife passing mechanism 60 includes: a feeding cutter-passing mounting seat 61, a feeding cutter-passing bearing 63 and a feeding cutter presser 62; the pay-off is crossed arbor and is held 63 and is equipped with two pairs, and respectively with the pay-off is crossed on the both sides of sword mount pad 61, pay-off knife pressing ware 62 is located two pairs between the arbor is held 63 to the pay-off is crossed, and is every right the arbor is held 63 interval setting is crossed in the pay-off, the middle part of pay-off knife pressing ware 62 is equipped with pay-off knife pressing groove 64, knife pressing groove and every right the interval play that the arbor was held 63 is crossed in the pay-off corresponds, and is concrete, and the setting of the knife mechanism 60 is crossed between pay-off subassembly 40 and the die-cut subassembly 70 in bridge position to the pay-off, avoids the sword material because of the extrusion of pay-off subassembly 40 under, leads to the sword material perk, and the arbor is held 63 is crossed in the pay-off of both sides and is used for protecting the horizontal pay-off of sword material in predetermined track, and pay-off knife pressing ware 62 is used for flattening the sword material, avoids appearing the condition of perk because of extrusion.

Further, as shown in fig. 7-8, in this embodiment, the bridge punch assembly 70 further comprises: the bridge position base 73 is provided with a bridge position sliding assembly 74 in a sliding manner, one end of the bridge position base 73 is provided with a die mounting plate 75, one end of the die mounting plate 75 is provided with two placing positions 751 arranged at intervals, the first die 80 and the second die 90 are detachably connected with the corresponding placing positions 751, the punching mechanism 71 is arranged in the middle of the bridge position base 73, one end of the placing position 751 is provided with a clamping block 752, the side wall of one end of the bridge position base 73 provided with the placing positions 751 is further provided with a guide bearing 753, specifically, the bridge position sliding assembly 74 adopts a screw rod mechanism which is common in the market, so that description is not given here, the die mounting plate 75 is connected with the screw rod mechanism, the bridge position sliding assembly 74 drives the die mounting plate 75 to move synchronously during operation, and the moving direction of the bridge position sliding assembly 74 is consistent with the moving directions of the cutter head assembly 20 and the material receiving tray assembly 100, the die mounting plate 75 is provided with two placing positions 751 at intervals at one end, the first die 80 and the second die 90 are detachably connected with the corresponding placing positions 751 respectively, when the die mounting plate 75 is driven by the bridge sliding assembly 74 to move, the first die 80 and the second die 90 on the die mounting plate are driven to move, so that one of the cutting dies 831 on the first die 80 or the second die 90 corresponds to a cutting material, one die is selected to cut the cutting material through the punching mechanism 71, a fixture block 752 is arranged at one end of the placing position 751 and used for fixing the first die 80 and the second die 90, a guide bearing 753 is further mounted on a side wall at one end of the bridge base 73 where the placing position is arranged, and the guide bearing 753 is used for limiting the cutting material to move in the conveying process and avoiding the direction of the guide bearing 753.

Further, as shown in fig. 12, in the present embodiment, the first mold 80 includes: a first base 81, a first guide plate 82, a first connecting member 83; the first base 81 is arranged in one of the placing positions 751, the first guide plate 82 is arranged above the first base 81, a plurality of penetrating guide holes 821 are arranged in the first guide plate 82, the first connecting piece 83 is positioned above the first guide plate 82, a plurality of cutting dies 831 are arranged on the first connecting piece 83 at intervals, the first guide holes 821 are matched with the corresponding cutting dies 831, a plurality of first back plates 84 are further laid on the first base 81, first through holes 841 which are matched with the cutting dies 831 one by one are arranged on the first back plates 84, and the first guide plate 82 and the first back plates 84 are arranged at intervals; the two sides of the top of the first connecting member 83 are respectively provided with a horizontally extending convex portion 832, the middle of the first connecting member 83 is provided with a first sliding groove 833, two side walls of the first sliding groove 833 are respectively provided with a first limiting groove 834, the top of the cutting die 831 is penetrated with a first limiting column 835, the first limiting column 835 is matched with the first limiting groove 834, one end of the first base 81 is provided with a first clamping groove 811, concretely, the second die 90 has the same structure as the first die 80, the second die 90 has a different specification from the cutting die 831 in the first die 80, the first die 80 comprises a first base 81, the first base 81 is arranged in one of the placing positions 751, the first guide plate 82 is fixedly arranged above the first base 81, the first connecting member 83 is arranged above the first guide plate 82, a plurality of cutting dies 831 with different specifications are arranged on the first connecting piece 83 side by side at intervals, a plurality of guide holes 821 which correspond to the cutting dies 831 in a one-to-one manner and are matched with the cutting dies 831 are formed in the first guide plate 82, the cutting dies 831 can penetrate through the first guide plate 82 through the guide holes 821 and can only move along the guide holes 821 under the limitation of the guide holes 821, a first back plate 84 is further laid on the first base 81, first through holes 841 which correspond to the cutting dies 831 in a one-to-one manner are formed in the first back plate 84, the first back plate 84 and the first guide plate 82 are arranged at intervals so that the cutting materials can conveniently penetrate out, when punching is carried out, the first connecting piece 83 is connected with the punching mechanism 71, and the cutting dies 831 can move along the guide holes 821 under the driving of the punching mechanism 71 to punch the cutting materials between the first back plate 84 and the first guide plate 82; the cutting die comprises a first connecting piece 83, a cutting die 831, a first limiting groove 834, a first limiting column 835, a first sliding groove 833, a first limiting groove 834 and a guide hole 821, wherein two sides of the top of the first connecting piece 83 are respectively provided with a protrusion 832 extending horizontally, the middle of the first connecting piece 83 is provided with the first sliding groove 833, the cutting die 831 is placed in the first connecting piece 83 through the first sliding groove 833, two sides of the first sliding groove 833 are respectively provided with the first limiting groove 834, one end of the first cutting die 831 penetrates through the first limiting column 835, the first limiting column 835 is matched with the first limiting groove 834, when the first cutting die 831 is positioned in the first sliding groove 833, the first limiting column 835 is positioned in the first limiting grooves 834 on two sides, so that the limitation in the vertical direction is realized, and the front and back direction of the first cutting die 831 is limited through the guide hole 821; the first locking groove 811 is used for being in snap fit with the clamping block 752, the first die 80 is fixed on the placing position 751, and when a die set needs to be replaced, the first die 80 can be replaced by directly detaching the clamping block 752.

Further, as shown in fig. 9 to 11, in the present embodiment, the die-cutting mechanism 71 includes: the punching machine comprises a punching base 711, wherein the punching base 711 is arranged on the bridge position base 73 in a crossing manner, the first die 80 and the second die 90 are positioned in the punching base 711, a motor mounting seat 712 is fixedly connected above the punching base 711, a punching motor 713 is fixedly connected in the motor mounting seat 712, the output end of the punching motor 713 penetrates out of the motor mounting seat 712 and is connected with an eccentric shaft 714, a punching sliding plate 715 is sleeved on the outer side of the eccentric shaft 714, the punching sliding plate 715 is in sliding connection with the motor mounting seat 712, the bottom end of the punching sliding plate 715 is connected with a punching pressing seat 716, the punching pressing seat 716 is provided with two avoiding positions 717 for placing the first die 80 and the second die 90, a placing hole 718 is arranged in one end of the punching sliding plate, which is connected with the eccentric shaft 714, the eccentric shaft 718 is positioned in the placing hole 718, the diameter of the placing hole 718 is larger than that of the eccentric shaft 714, inserts 719 are respectively arranged at two vertical ends of the placing hole 718, the inserts 719 and the eccentric shaft 714 abut against the eccentric shaft 714, and the eccentric shaft 714 can horizontally slide in the placing hole; the punching press seat 716 is internally provided with a transposition sliding groove 720 penetrating through the two avoidance positions 717, the top of the transposition sliding groove 720 is provided with a punching limiting groove 721, the punching press block 76 is slidably arranged in the transposition sliding groove 720, the top of the punching press block 76 is provided with a limiting bump 722, the limiting bump 722 is matched with the punching limiting groove 721, one side of the punching press seat 716 is further provided with a transposition air cylinder 723, and the output end of the transposition air cylinder 723 is fixedly connected with the punching press block 76.

Specifically, the punching base 711 is arranged on the bridge position base 73 in a crossing manner, the first die 80 and the second die 90 are arranged in the punching base 711, the motor mounting seat 712 is fixedly arranged on the top of the punching base 711, the punching motor 713 is fixed on the motor mounting seat 712, the output end of the punching motor 713 is positioned outside the motor mounting seat 712 and is connected with an eccentric shaft 714, a punching sliding plate 715 is sleeved on the outer side of the eccentric shaft 714, the eccentric shaft 714 can rotate relative to the punching sliding plate 715, the punching sliding plate 715 is driven to move correspondingly when the eccentric shaft 714 rotates, the punching sliding plate 715 is connected with the motor mounting seat 712 in a sliding manner, the punching sliding plate 715 can slide along the motor mounting seat 712 under the driving of the eccentric shaft 714, the bottom of the punching sliding plate 715 is fixedly connected with the punching pressing seat 716, the punching pressing seat 716 is driven to move synchronously when the sliding plate 715 moves, and the punching pressing seat 716 drives the punching pressing block 76 to press the first die 80 or the second die 90, so as to punch the material.

Furthermore, in order to prevent the eccentric shaft 714 from rotating to drive the punching slide plate 715 to rotate, a placing hole 718 is formed at one end of the punching slide plate 715, which is far away from the punching press seat 716, the eccentric shaft 714 is located in the placing hole 718, and the aperture of the placing hole 718 is larger than that of the eccentric shaft 714, so that the eccentric shaft 714 can rotate in the placing hole 718, and at the same time, in order to realize that the eccentric shaft 714 only drives the punching slide plate 715 to move vertically, the insert 719 is respectively clamped at two vertical ends of the placing hole 718, and abuts against the eccentric shaft 714 through the insert 719, but is not limited to slide relative to the insert 719 of the eccentric shaft 714, so that the eccentric shaft 714 can drive the punching slide plate 715 to move up and down synchronously due to the limitation of the insert 719 when the eccentric shaft 714 rotates to the up and down position, and when the eccentric shaft rotates to the left and right position, the diameter of the placing hole 718 is larger than that of the eccentric shaft 714, and the insert 719 is not provided at the left and right sides, so that the eccentric shaft 714 can slide left and right in the placing hole 718, and the punching slide left and right direction, and the punching slide plate 715 is cancelled by a sliding stroke, so that the eccentric 714 can only drive the punching slide left and right slide up and right movement of the eccentric shaft 715 when rotating.

Furthermore, a transposition sliding groove 720 penetrating through two avoidance positions 717 is further formed in the punching press seat 716, the punching press block 76 is located in the transposition sliding groove 720, a punching limiting groove 721 is further formed in the top of the transposition sliding groove 720, a limiting bump 722 matched with the punching limiting groove 721 is arranged on the top of the punching press block 76, the punching press block 76 is fixed in the transposition sliding groove 720 through the limiting bump 722 to avoid falling, and can slide in the limitation sliding groove through the limiting bump 722, the punching press block 76 can be moved to the preset avoidance positions 717 according to requirements during operation to correspond to the first mold 80 or the second mold 90, and accordingly the corresponding molds are driven to move.

It should be noted that, horizontal inwardly extending hook blocks are respectively arranged on two side walls of the bottom of each avoidance portion 717, the hook blocks are matched with the protruding portions 832 of the first connecting blocks, when the first mold 80 and the second mold 90 are placed in the avoidance portions 717, the first mold 80 and the second mold 90 are prevented from being separated from the avoidance portions 717 through the matching of the hook blocks and the protruding portions 832, meanwhile, because the first mold 80 and the second mold 90 do not have resetting capability, resetting of the first mold 80 and the second mold 90 can also be realized through the hook blocks, that is, when the punching press seat 716 slides down under the driving of the eccentric shaft 714, the punching press block 76 presses the corresponding first connecting piece 83 to slide down, when the punching press seat 716 ascends under the driving of the eccentric shaft 714, the first mold 80 and the second mold 90 are synchronously driven to ascend through the matching of the hook blocks and the protruding portions 832, so that the first mold 80 and the second mold 90 can return to the original position after one stroke is finished, and the next work is facilitated.

Further, in order to realize automatic control of the sliding of the punching press block 76, a transposition cylinder 723 is arranged on one side of the punching press seat 716, an output end of the transposition cylinder 723 is fixedly connected with the punching press block 76, and the punching press block 76 is driven to slide in the transposition sliding chute 720 through the output of the transposition cylinder 723.

Further, in this embodiment, pay-off subassembly 40 with still be equipped with between the die-cut subassembly 70 in bridge position and beat the mark subassembly (not shown in the figure), beat the mark subassembly and be used for printing predetermined pattern and or characters to the cutter surface, specifically, beat the mark subassembly and be laser marking, be located the pay-off and cross the top of sword mechanism 60 for print predetermined pattern and or characters and or LOGO to the cutter surface.

In summary, according to the present invention, the cutter head assembly 20 is provided with the plurality of placing discs 21 with different specifications, so that the cutter head assembly 20 can simultaneously place the cutters with multiple specifications, and the corresponding placing discs 21 are controlled by the translation mechanism 23 to correspond to the feeding assembly 30, so as to achieve feeding of the cutters with preset specifications, thereby saving frequent material changing steps, and meanwhile, the first mold 80 and the second mold 90 are provided in the bridge punching assembly 70, so as to achieve expansion of the punching range, and achieve selectivity of the molds by punching the pressing block 76, thereby improving convenience of the use of the apparatus.

The invention is not limited to only that described in the specification and embodiments, and thus additional advantages and modifications will readily occur to those skilled in the art, and it is not intended to be limited to the specific details, representative apparatus, and illustrative examples shown and described herein, without departing from the spirit and scope of the general concept as defined by the appended claims and their equivalents.

Claims (11)

1. The utility model provides an collect many specifications die-cutting rule production facility which characterized in that includes: the device comprises a cutter head assembly, a feeding assembly, a bridge position punching assembly, a material receiving tray assembly and a workbench; the cutting device comprises a workbench, a feeding component, a bridge punching component, a receiving tray component, a cutter component, a feeding component, a bridge punching component, a receiving tray component and a cutter component, wherein the cutter component is positioned on one side of the workbench, the receiving tray component is positioned on one side of the workbench opposite to the cutter component, the feeding component and the bridge punching component are sequentially arranged on the workbench, the feeding component is positioned corresponding to the cutter component, the bridge punching component corresponds to the receiving tray component, a plurality of placing trays with different sizes are arranged on the cutter component and used for placing cutters, the placing trays can move along the width direction of the workbench, a plurality of collecting grooves which are matched with the placing trays one by one are arranged on the receiving tray component, and the receiving tray component can move along the width direction of the workbench; the feeding assembly is used for pulling out and delivering to the knife material in the cutter head assembly in the feeding assembly, the feeding assembly is used for delivering the knife material that the feeding assembly carried to in the die-cut subassembly of bridge position, the die-cut subassembly of bridge position includes: the punching mechanism comprises a first die, a second die and a punching mechanism, wherein a plurality of cutting dies with different sizes are arranged on the first die and the second die respectively, the first die and the second die are arranged at the bottom of the punching mechanism side by side, a punching press block is arranged in the punching mechanism in a sliding manner, and the punching mechanism is used for selecting one of the first die and the second die to drive punching through the punching press block.

2. The apparatus for producing a multi-specification assembly cutting rule according to claim 1, wherein the cutter head assembly comprises: a frame, a translation mechanism; the translation mechanism is arranged at the top of the rack, a cutter head base is connected to the translation mechanism, the placing discs are arranged on the cutter head base side by side, and the translation mechanism is used for driving the cutter head base to move along a preset direction.

3. The mold cutting rule production equipment with multiple specifications according to claim 1, wherein a plurality of material blocking shafts are arranged in each placing disc, the material blocking shafts are arranged in the placing discs in a semicircular shape, each material blocking shaft is rotatably provided with a roller, a guide block which is matched with the top of each placing disc is fixedly arranged at the top of each placing disc, the guide block is horizontally arranged, a cutter pressing cylinder is further arranged on the guide block and used for pressing the cutter materials at a preset stage, and a through discharge hole is formed in the middle of the guide block and used for outputting the cutter materials.

4. The apparatus for producing the multi-specification die-cutting rule according to claim 1, wherein the feeding assembly is in transmission connection with the feeding assembly, and the feeding assembly comprises: the feeding installation base is internally and fixedly provided with a feeding lower roller, a feeding upper roller is arranged above the feeding installation base in a sliding mode, the feeding lower roller is opposite to the feeding upper roller, and the feeding upper roller can move towards the direction of the feeding lower roller.

5. The integrated multi-specification die-cutting rule production equipment according to claim 4, wherein the feeding assembly comprises: the feeding device comprises a feeding mounting base, wherein a feeding lower roller is fixedly arranged in the bottom of the feeding mounting base, a feeding upper roller is arranged above the feeding mounting base in a sliding mode and is opposite to the feeding lower roller, the feeding upper roller can move towards the direction of the feeding lower roller, the feeding lower roller is connected with a feeding motor, and the feeding lower roller is in transmission connection with the feeding lower roller.

6. The apparatus for producing the mold-cutting rule integrating multiple specifications as claimed in claim 1, wherein a feeding and knife passing mechanism is further arranged between the feeding assembly and the feeding assembly, and the feeding and knife passing mechanism comprises: the feeding cutter passing bearing, the feeding cutter passing mounting seat and the feeding cutter pressing device are arranged on the feeding cutter passing bearing; the feeding cutter shaft bearing is provided with two pairs of feeding cutter shaft bearings which are respectively arranged on two sides of the feeding cutter shaft bearing mounting seat, the feeding cutter pressing device is positioned between the two pairs of feeding cutter shaft bearings, each pair of feeding cutter shaft bearings are arranged at intervals, the middle part of the feeding cutter pressing device is provided with a feeding cutter pressing groove, and the cutter pressing groove corresponds to the interval between each pair of feeding cutter shaft bearings.

7. The apparatus for producing a mold-cutting rule integrating multiple specifications as claimed in claim 1, wherein a feeding and passing mechanism is further arranged between the feeding assembly and the bridge position punching assembly, and the feeding and passing mechanism comprises: a feeding cutter passing mounting seat, a feeding cutter passing bearing and a feeding cutter pressing device; the feeding cutter passing shaft bearings are provided with two pairs and are respectively arranged on two sides of the feeding cutter passing mounting seat, the feeding cutter pressing device is positioned between the two pairs of feeding cutter passing shaft bearings, each pair of feeding cutter passing shaft bearings are arranged at intervals, the middle part of the feeding cutter pressing device is provided with a feeding cutter pressing groove, and the cutter pressing groove corresponds to each pair of feeding cutter passing shaft bearings at intervals.

8. The apparatus for producing a multi-specification cutting rule according to claim 1, wherein the bridge punching assembly further comprises: the bridge position base, it is equipped with bridge position slip subassembly to slide on the bridge position base, the one end of bridge position base is equipped with the mould mounting panel, the one end of mould mounting panel is equipped with the position of placing that two intervals set up, first mould with the second mould with correspond place the position and can dismantle the connection, die-cutting mechanism locates the middle part of bridge position base, the one end of placing the position is equipped with the fixture block, the bridge position base is equipped with place the one end lateral wall of position and still install guide bearing.

9. The integrated multi-specification die-cutting rule production equipment according to claim 1, wherein the first die comprises: the device comprises a first base, a first guide plate and a first connecting piece; the first base is arranged in one of the placing positions, the first guide plate is arranged above the first base, a plurality of penetrating guide holes are formed in the first guide plate, the first connecting piece is positioned above the first guide plate, a plurality of cutting dies are arranged on the first connecting piece at intervals, the first guide holes are matched with the corresponding cutting dies, a plurality of first back plates are further paved on the first base, first through holes matched with the cutting dies one by one are formed in the first back plates, and the first guide plate and the first back plates are arranged at intervals; the cutting die is characterized in that horizontally extending protruding portions are arranged on two sides of the top of the first connecting piece respectively, a first sliding groove is formed in the middle of the first connecting piece, first limiting grooves are formed in two side walls of the first sliding groove respectively, a first limiting column is arranged at the top of the cutting die in a penetrating mode, the first limiting column is matched with the first limiting grooves, and a first clamping groove is formed in one end of the first base.

10. The integrated multi-specification die-cutting rule production equipment according to claim 1 or 8, wherein the die-cutting mechanism comprises: the punching base is arranged on the bridge position base in a crossing mode, the first module and the second module are located in the punching base, a motor mounting seat is fixedly connected above the punching base, a punching motor is fixedly connected in the motor mounting seat, the output end of the punching motor penetrates out of the motor mounting seat and is connected with an eccentric shaft, a punching sliding plate is sleeved on the outer side of the eccentric shaft and is connected with the motor mounting seat in a sliding mode, the bottom end of the punching sliding plate is connected with a punching pressing seat, the punching pressing seat is provided with two avoidance positions for placing the first die and the second die, a placing hole is formed in one end, connected with the eccentric shaft, of the punching sliding plate, the eccentric shaft is located in the placing hole, the diameter of the placing hole is larger than that of the eccentric shaft, inserts are respectively arranged at two vertical ends of the placing hole and abut against the eccentric shaft, and the eccentric shaft can horizontally slide in the placing hole; the die-cut pressure seat is internally provided with two transposition chutes which run through the avoidance, the top of the transposition chute is provided with a die-cut limiting groove, the die-cut pressing block is arranged in the transposition chute in a sliding manner, the top of the die-cut pressing block is provided with a limiting lug, the limiting lug is matched with the die-cut limiting groove, one side of the die-cut pressure seat is also provided with a transposition cylinder, and the output end of the transposition cylinder is fixedly connected with the die-cut pressing block.

11. The production equipment of the multi-specification die-cutting rule as claimed in claim 1, wherein a marking assembly is further arranged between the feeding assembly and the bridge punching assembly and is used for printing preset patterns and/or characters on the surface of the cutting tool.

Images