CN214520579U - Die-cutting machine capable of synchronously discharging waste - Google Patents

Abstract

The utility model relates to a cross cutting machine of synchronous waste discharge, it includes the workstation, connects the cross cutting machine body on the workstation, still including connecting the press device on the workstation, receiving useless device, press device and receive useless device and be located the one side of the ejection of compact of cross cutting machine body, press device is including the first material subassembly of pressing that is used for compressing tightly sponge piece and waste material, the second material subassembly of pressing that is used for compressing tightly the sponge piece, receive useless device including connecting the support on the workstation, rotate wind-up axle, the transmission of connection on the support and connect the epaxial driving piece of wind-up. The application has the effects of synchronous waste discharge and efficiency improvement.

Description

Die-cutting machine capable of synchronously discharging waste

Technical Field

The application relates to the field of sponge processing, in particular to a synchronous waste discharge die-cutting machine.

Background

Sponges are widely used in production and daily life, for example, inner cores of bedding, seals of various appliances, etc., because of their excellent elasticity. The sponge can be processed before being used as the sealing sheet, and can be used for actual products after being cut into various sizes, and most of sponge cutting is processed by adopting a die cutting machine. Before cutting by the die cutting machine, the sponge is adhered to the release paper to be rolled, when the die cutting machine is used for processing, the sponge is cut on the release paper, and after cutting is completed, the waste material is torn off from the release paper to obtain the sponge sheet adhered to the release paper.

Chinese patent No. CN202825953U discloses a die-cutting machine with an alarm indicator, which comprises a feeding table with air holes on the surface, a bonding system, a die-cutting system, a numerical control device, a machine body, an input display panel and an alarm indicator, wherein the feeding table with air holes on the surface, the bonding system and the die-cutting system are sequentially arranged on the upper surface of the machine body; the numerical control device is positioned on the left side of the machine body; a support frame is arranged on the right side of the machine body, and an input display panel, a material placing frame and an alarm indicator lamp are arranged on the support frame; the alarm indicator lamp is divided into three sections, namely a normal operation indicator lamp, a stop operation indicator lamp and a fault indicator lamp from bottom to top in sequence.

With respect to the related art in the above, the inventors consider that there are the following drawbacks: the die-cutting machine cannot synchronously discharge waste after the die-cut product is finished, and needs subsequent manual waste discharge or reuse of a special waste discharge device, so that the efficiency is low.

SUMMERY OF THE UTILITY MODEL

In order to arrange useless in step, raise the efficiency, this application provides the cross cutting machine of synchronous waste discharge.

The application provides a die-cutting machine of synchronous waste discharge adopts following technical scheme:

the utility model provides a synchronous waste discharge's cross cutting machine, includes the workstation, connects the cross cutting machine body on the workstation, still includes the press device of connection on the workstation, receives useless device, press device and receive useless device and be located the one side of the ejection of compact of cross cutting machine body, press device presses the material subassembly including the first pressure material subassembly that is used for compressing tightly sponge piece and waste material, the second that is used for compressing tightly the sponge piece, receive useless device including connect the support on the workstation, rotate wind-up shaft, the transmission of connection on the support and connect the epaxial driving piece of wind-up.

By adopting the technical scheme, after the sponge is cut by the die cutting machine body, the sponge passes through the first pressing assembly, the waste materials cut from the sponge are wound by the winding shaft, and the release paper and the product cut and formed from the release paper pass through the second pressing assembly and are subsequently processed by workers; the waste collecting device collects waste materials automatically under the cooperation of the pressing device, and work efficiency is greatly improved.

Optionally, the support is fixedly connected to the workbench, the winding shaft is rotatably connected to the top end of the support, the axis of the winding shaft is perpendicular to the conveying direction, and the driving piece is a driving motor fixedly connected to the support.

Through adopting above-mentioned technical scheme, fix the one end of the waste material that is cut off on the sponge on the rolling axle, driving motor orders about the rolling axle rotatory, and the rolling axle tears the waste material from type paper and winds the lapping.

Optionally, the first material pressing assembly comprises a second bottom plate connected to the workbench, a first installation shaft horizontally erected on the second bottom plate, a first material pressing wheel horizontally erected on the first installation shaft, a pressing rod horizontally erected on the workbench, and a pressing sheet fixedly connected to the pressing rod, the second bottom plate is located on the discharge side of the die cutting machine body, the first installation shaft is perpendicular to the material conveying direction, the first material pressing wheel is attached to the second bottom plate, and the pressing sheet is arranged along the length direction of the pressing rod.

Through adopting above-mentioned technical scheme, first nip wheel compresses tightly the sponge with the compact heap before wind-up roll rolling waste material, has reduced the wind-up roll and has torn the possibility that the sponge influences the cross cutting precision.

Optionally, one side of the second bottom plate, which deviates from the die cutting machine body, is connected with an arc-shaped plate which bends downwards, one side of the pressing sheet is attached to the arc-shaped plate, and the second pressing assembly comprises a second mounting shaft which is horizontally connected to the workbench, and a second pressing wheel which is sleeved on the second mounting shaft in a sliding manner.

Through adopting above-mentioned technical scheme, the separation that waste material and release paper can be realized better to second swager cooperation wind-up roll.

Optionally, the first pressing wheel is provided with a first positioning piece, and the second pressing wheel is provided with a second positioning piece.

By adopting the technical scheme, the possibility that the material pressing effect is influenced by the fact that the first material pressing wheel slides on the first mounting shaft and is staggered with the sponge during working is reduced; the possibility that the second pressing wheel slides on the second mounting shaft and is staggered with the sponge to influence the pressing effect during working is reduced.

Optionally, one side of the die cutting machine body for feeding is provided with an unwinding frame and a limiting device, and the limiting device is located between the unwinding frame and the die cutting machine body.

Through adopting above-mentioned technical scheme, the sponge is accurate under stop device's effect and is transmitted this internal cutting of cross cutting machine, has improved cutting accuracy.

Optionally, stop device establishes limiting plate, horizontally connect the installation pole on the support frame, the preforming of connection on the installation pole including support frame, the back-up roll of horizontally connect on the support frame, cover on the back-up roll, back-up roll perpendicular to defeated material direction sets up, the limiting plate is provided with two, the installation pole is located the back-up roll top, the preforming deviates from the one end pressure of installation pole on the back-up roll.

Through adopting above-mentioned technical scheme, the one end of sponge passes from between backing roll and the installation roller, and the sponge transmits between two limiting plates, and two preforming are pressed the sponge on the backing roll.

Optionally, a horizontal first bottom plate is arranged between the pressing plate and the die cutting machine body, the first bottom plate is fixedly connected to the supporting frame, a horizontal first pressing plate is arranged on the first bottom plate, and a gap is reserved between the first pressing plate and the first bottom plate.

Through adopting above-mentioned technical scheme, first clamp plate and first bottom plate have further improved the planarization when sponge gets into cross cutting machine.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the pressing device and the waste collecting device are arranged, and the waste collecting device automatically collects waste materials under the cooperation of the pressing device, so that the working efficiency is greatly improved;

2. the first material pressing wheel and the pressing piece are arranged, the sponge is pressed before the winding roller winds the waste materials, and the possibility that the winding roller pulls the sponge to influence the die cutting precision is reduced;

3. set up stop device, the sponge is accurate under stop device's effect and is transmitted this internal cutting of cross cutting machine, has improved cutting accuracy.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present application;

FIG. 2 is a schematic structural diagram of a limiting device in the embodiment of the present application;

FIG. 3 is a schematic structural diagram of a pressing device and a waste recycling device in an embodiment of the application;

FIG. 4 is an enlarged view at A in FIG. 3;

FIG. 5 is a schematic structural view of a hold-down assembly in an embodiment of the present application;

fig. 6 is an enlarged view of fig. 3 at B.

Description of reference numerals: 1. unwinding the frame; 11. a chassis; 12. erecting a frame; 13. unwinding the reel; 2. a work table; 21. a transverse plate; 211. mounting grooves; 212. a screw rod; 213. a movable seat; 214. a spring; 3. a limiting device; 31. a support frame; 32. a support roller; 33. mounting a rod; 331. a sliding sleeve; 332. locking the screw rod; 333. tabletting; 34. a limiting plate; 35. a connecting rod; 351. a locking sleeve; 352. a locking lever; 36. a first base plate; 361. a first platen; 37. mounting a plate; 38. a limiting block; 4. a die cutting machine body; 5. a waste collection device; 51. a support; 511. a support plate; 512. a cross arm; 52. a winding shaft; 53. a drive motor; 54. a guide bar; 541. a sliding seat; 6. a pressing device; 7. a first swaging assembly; 71. a second base plate; 711. a through groove; 72. a first mounting shaft; 721. a first nip wheel; 722. a first positioning ring; 723. a first positioning screw; 73. a hold down bar; 731. a compression sheet; 74. an adjusting bracket; 741. a rotating shaft; 742. an adjusting plate; 75. a compression assembly; 751. a rotating plate; 7511. a first mounting block; 7512. a second mounting block; 7513. a fixing plate; 752. a compression screw; 753. a pressure spring; 754. a pinch roller; 755. a second platen; 76. a first conveying roller; 761. a driving wheel; 77. a conveying motor; 78. an arc-shaped plate; 8. a second swaging assembly; 81. a second mounting shaft; 82. a second nip wheel; 83. a second conveying roller; 831. a driven wheel; 832. a belt; 84. a second positioning ring; 85. and a second positioning screw.

Detailed Description

The present application is described in further detail below with reference to figures 1-6.

The embodiment of the application discloses die cutting machine capable of synchronously discharging waste.

Referring to fig. 1, the die cutting machine capable of discharging waste synchronously comprises a unreeling frame 1, a workbench 2, a limiting device 3, a die cutting machine body 4, a pressing device 6 and a waste collecting device 5, wherein the limiting device 3, the die cutting machine body 4, the pressing device and the waste collecting device are sequentially arranged on the workbench 2 along a material conveying direction.

Referring to fig. 1, the unwinding frame 1 includes a base frame 11 placed on the ground, stand frames 12 fixedly connected to both ends of the base frame 11, and a horizontal unwinding shaft 13 placed on the top ends of the stand frames 12. The bottom of the underframe 11 is rotatably connected with a travelling wheel, and an inclined reinforcing rod is fixedly connected between the underframe 11 and the vertical frame 12. Roll up the cover with the sponge material on unreeling axle 13, the one end of sponge gets into cross cutting machine body 4 through stop device 3, and via cross cutting machine body 4 cutting back, receive useless device 5 and collect the waste material automatically under press device 6's cooperation, improved work efficiency greatly.

Referring to fig. 1 and 2, the stopper 3 includes a support frame 31 fixedly coupled to the table 2, a horizontal support roller 32 fixedly coupled to the support frame 31, and a mounting rod 33. The supporting rollers 32 are arranged perpendicular to the material conveying direction, the supporting rollers 32 correspond to the feeding position of the die cutting machine body 4, and three supporting rollers 32 are arranged along the length direction of the workbench 2. The support rollers 32 are sleeved with two limit plates 34, and the limit plates 34 are connected with the three support rollers 32. The mounting rod 33 is positioned above the middle support roller 32, and two pressing pieces 333 which are obliquely arranged are connected to the mounting rod 33. A sliding sleeve 331 which is sleeved on the mounting rod 33 in a sliding mode is fixed at one end of the pressing sheet 333, a locking screw 332 is connected to the sliding sleeve 331 in a threaded mode, and the other end of the pressing sheet 333 is attached to the side wall of the supporting roller 32 close to the die cutting machine body 4.

Referring to fig. 1 and 2, one end of the sponge passes through the supporting roller 32 and the mounting roller, the sponge is transmitted between the two limiting plates 34, the two pressing sheets 333 press the sponge on the supporting roller 32, and the sponge is accurately transmitted into the die cutting machine body 4 for cutting under the action of the limiting device 3, so that the cutting precision is improved. The position of the pressing sheet 333 is adjustable, and the sponge limiting device can be suitable for limiting sponges with various widths.

Referring to fig. 2, the limiting plates 34 are slidably connected to the supporting rollers 32, a horizontal connecting rod 35 is arranged between each two adjacent supporting rollers 32, the connecting rod 35 is parallel to the supporting rollers 32, and the connecting rod 35 is fixedly connected to the supporting frame 31. The connecting rod 35 penetrates through the limiting plate 34 and is in sliding fit with the limiting plate 34, and a locking piece is arranged on the connecting rod 35. The locking member comprises a locking sleeve 351 which is slidably sleeved on the connecting rod 35 and a locking rod 352 which is in threaded connection with the locking sleeve 351. The locking sleeve 351 is fixedly connected to the side wall of the limiting plate 34 opposite to the sponge, and when the locking rod 352 is screwed down, one end of the locking rod 352 is abutted against the connecting rod 35.

Referring to fig. 2, when sponges with different widths need to be cut, the locking rod 352 is unscrewed, the limiting plate 34 is slid to the width suitable for the sponges, the locking rod 352 is screwed down, and the limiting plate 34 is fixed. The position of the limiting plate 34 is adjustable, and the applicability of the limiting device 3 to sponges with different widths is improved.

Referring to fig. 1 and 2, a horizontal first bottom plate 36 is fixedly connected to the supporting frame 31. The first bottom plate 36 is positioned between the pressing sheet 333 and the die cutting machine body 4, a horizontal first pressing plate 361 is connected to the first bottom plate 36 through bolts, and a gap for passing through sponge is reserved between the first bottom plate 36 and the first pressing plate 361. One side of the first bottom plate 36 departing from the pressing sheet 333 is connected with a mounting plate 37, and the mounting plate 37 is slidably connected with a limiting block 38. A chute is formed in the mounting plate 37 and perpendicular to the conveying direction, a sliding block connected in the chute in a sliding mode is formed at the bottom of the limiting block 38, and the limiting block 38 is arranged on two sides of the sponge. The first pressure plate 361 and the stop block 38 further improve the smoothness of the sponge as it enters the die cutting machine.

Referring to fig. 1 and 3, the pressing device 6 includes a first pressing assembly 7 for pressing the sponge sheet and the waste, and a second pressing assembly 8 for pressing the sponge sheet. The discharge department of cross cutting machine body 4 is equipped with second bottom plate 71, and second bottom plate 71 fixed connection is on workstation 2. The first swaging assembly 7 comprises a horizontal first mounting shaft 72 and a horizontal pressing rod 73 fixedly connected to the workbench 2, which are sequentially arranged along the feeding direction, and the first mounting shaft 72 and the pressing rod 73 are arranged perpendicular to the feeding direction.

Referring to fig. 3, an adjusting bracket 74 is rotatably connected to the table 2, and the adjusting bracket 74 includes a rotating shaft 741 rotatably connected to the table 2 in a width direction of the table 2 and an adjusting plate 742 fixedly connected to the rotating shaft 741. The rotation shaft 741 is located below the second bottom plate 71, one adjusting plate 742 is disposed on each of two sides of the second bottom plate 71, and the first mounting shaft 72 is fixedly connected between the two adjusting plates 742. The worktable 2 is further provided with a pressing assembly 75 for pressing the adjusting bracket 74.

Referring to fig. 3, the workbench 2 is rotatably connected with a first conveying roller 76, the first conveying roller 76 is located under the first installation shaft 72, one end of the first conveying roller 76 is connected with a conveying motor 77 in a transmission manner, and the conveying motor 77 is fixedly connected to the side wall of the workbench 2. The first conveying roller 76 is located below the second base plate 71, and a through groove 711 is formed in the second base plate 71 in the width direction thereof, and the through groove 711 corresponds to the first conveying roller 76.

Referring to fig. 3, two first swaging wheels 721 are sleeved on the first mounting shaft 72, the first swaging wheels 721 are connected to the first mounting shaft 72 through bearings, and the first swaging wheels 721 are in rotational fit or sliding fit with the first mounting shaft 72. The first nip wheel 721 and the first conveying roller 76 are controlled to be close to each other in the through groove 711 by the pressing assembly 75. The sponge cut by the die cutter body 4 passes out between the first feed roller 76 and the first nip wheel 721. The first conveying roller 76 is controlled to rotate by the conveying motor 77, and the first conveying roller 76 and the first nip wheel 721 cooperate to convey the sponge.

Referring to fig. 3 and 4, in order to reduce the possibility that the first nip wheel 721 slides on the first mounting shaft 72 during operation and is misaligned with the sponge to affect the pressing and transporting effects, a first positioning member is provided on the first nip wheel 721. The first positioning member includes a first positioning ring 722 slidably fitted on the first mounting shaft 72, and a first positioning screw 723 threadedly coupled to a sidewall of the first positioning ring 722. The first positioning ring 722 is fixedly connected to an inner ring of a bearing on the first swaging wheel 721, and when the first positioning screw 723 is screwed down, one end of the first positioning screw 723 abuts against the first mounting shaft 72 to fix the position of the first swaging wheel 721 on the first mounting shaft 72 without affecting the rotation of the first swaging wheel 721.

Referring to fig. 3 and 5, the pressing assembly 75 includes a rotating plate 751 rotatably coupled to the table 2, a pressing screw 752 coupled to the rotating plate 751 along a length direction of the rotating plate 751, a pressing spring 753 fitted over the pressing screw 752, a pressing roller 754 coupled to a bottom end of the pressing screw 752, and a second pressing plate 755 fixedly coupled between the two adjusting plates 742. The top end of the rotating plate 751 is fixedly connected with a first mounting block 7511, and the bottom end is slidably connected with a second mounting block 7512.

Referring to fig. 3 and 5, the compression screw 752 is screwed on the first mounting block 7511, the bottom end of the compression screw is rotatably connected with the second mounting block 7512, and the compression spring 753 is abutted between the first mounting block 7511 and the second mounting block 7512. One side of the second mounting block 7512 is slidably connected to the rotation plate 751 through a slide bar, and a slide groove for the slide bar to slide is formed in the rotation plate 751 along the length direction thereof. The other side of the second mounting block 7512 is fixedly connected with a fixing plate 7513, the press wheel 754 is rotatably connected on the fixing plate 7513, and the axis of the press wheel 754 is vertical to the material conveying direction.

Referring to fig. 1 and 5, the end of the adjustment plate 742 near the die cutter body 4 is curved to roll engage the press wheel 754.

Referring to fig. 3 and 5, the cut sponge is laid on the second bottom plate 71, the adjusting bracket 74 is rotated to press the second pressing plate 755 and the first pressing wheel 721 onto the sponge, the rotating plate 751 is rotated to position the pressing wheel 754 on the arc surface of the adjusting plate 742, and the pressing screw 752 is tightened. The pressing wheel 754 abuts against the adjusting plate 742, and the second pressing plate 755 and the first pressing wheel 721 are fixed. The degree of pressing of the pressing wheel 754 can be adjusted according to the thickness of the cut material, and the applicability is improved.

Referring to fig. 3, an arc plate 78 is integrally formed on a side of the second bottom plate 71 facing away from the die cutting machine body 4, and the arc plate 78 is bent downward. The pressing rod 73 is fixedly connected to the workbench 2 through a connecting block, and the pressing rod 73 is located above the arc plate 78. Pressing rod 73 is last along self length direction fixedly connected with pressing piece 731, and pressing piece 731 sets up in the slope, and the bottom of pressing piece 731 is a little higher than the top of arc 78.

Referring to fig. 3, the die-cut sponge passes between the first nip wheel 721 and the first conveying roller 76, and then passes through the pressing sheet 731. The waste material that is cut off on the sponge this moment is collected by receipts waste device 5, falls along arc 78 from type paper and from the last fashioned sponge piece of cutting of type paper, carries out subsequent processing by the staff.

Referring to fig. 3, the waste collecting device 5 includes a bracket 51 fixedly connected to the table 2, a horizontal winding shaft 52 rotatably connected to a top end of the bracket 51, and a driving member fixedly connected to the bracket 51. The top of the bracket 51 is fixedly connected with a support plate 511, and the support plate 511 is arranged along the length direction of the workbench 2. The winding shaft 52 is rotatably connected to one side of the supporting plate 511 close to the second bottom plate 71, and the axis of the winding shaft 52 is perpendicular to the feeding direction. The driving part is a driving motor 53, the driving motor 53 is fixedly connected to one side of the supporting plate 511, which is far away from the winding shaft 52, and the output shaft of the driving motor 53 is in transmission connection with the winding shaft 52.

Referring to fig. 3, a guide rod 54 is provided on the holder 51 in order to improve the regularity of the scrap take-up. A cross arm 512 is fixedly connected to one side of the bracket 51, which is far away from the die cutting machine body 4, and the guide rod 54 is slidably sleeved on the cross arm 512 through a sliding seat 541. The guide bar 54 is parallel to the take-up reel 52, and the guide bar 54 is located between the take-up reel 52 and the pressing bar 73.

Referring to fig. 3, the driving motor 53 drives the winding shaft 52 to rotate, and the winding shaft 52 tears the waste material off the release paper and winds the waste material into a roll. The release paper and the sponge sheet cut and formed on the release paper are separated from the waste under the action of the second pressing component 8.

Referring to fig. 3, the second pressing assembly 8 includes a second mounting shaft 81 horizontally connected to the worktable 2, and two second pressing wheels 82 slidably fitted on the second mounting shaft 81, and the second pressing wheels 82 are connected to the second mounting shaft 81 through bearings. One end fixedly connected with diaphragm 21 that workstation 2 is close to arc 78, and diaphragm 21 all is equipped with one in the both sides of arc 78, and second installation axle 81 erects between two diaphragms 21, and second pinch roller 82 is located the below of arc 78. The workbench 2 is rotatably connected with a second conveying roller 83, the second conveying roller 83 is located below the arc plate 78, and the second conveying roller 83 is parallel to the second mounting shaft 81. The second conveying roller 83 is located between the second mounting shaft 81 and the table 2, and the second conveying roller 83 is adjacent to the second pinch roller 82.

Referring to fig. 3, one end of the first conveying roller 76 is coaxially and fixedly connected with a driving wheel 761, one end of the second conveying roller 83 close to the driving wheel 761 is coaxially and fixedly connected with a driven wheel 831, a belt 832 is wound on the driving wheel 761 and the driven wheel 831, and the belt 832 is positioned below the second bottom plate 71. The driving motor 53 drives the first conveying roller 76 to rotate, the first conveying roller 76 drives the second conveying roller 83 to rotate through the transmission of the driving wheel 761, the belt 832 and the driven wheel 831, and the second conveying roller 83 is matched with the second pressing wheel 82 to convey the sponge.

Referring to fig. 3, the horizontal plate 21 is provided with a mounting groove 211 along the feeding direction, a screw rod 212 is rotatably connected in the mounting groove 211, and one end of the screw rod 212 penetrates out of the horizontal plate 21 and is fixedly connected with a handle. Threaded connection has the removal seat 213 on the lead screw 212, removes seat 213 and inlays in mounting groove 211 and with mounting groove 211 sliding fit, and second installation axle 81 is fixed between two removal seats 213. The screw 212 is sleeved with a spring 214, one end of the spring 214 abuts against the side wall of the movable seat 213, and the other end abuts against the side wall of the mounting groove 211. Screw 212 is twisted, and the movable seat 213 drives the second mounting shaft 81 to deviate from or move close to the second conveying roller 83, so that the sponge roller is suitable for sponges with different thicknesses.

Referring to fig. 3, in the material conveying process, the cut waste materials on the sponge are collected by the winding shaft 52, and the release paper and the sponge sheet on the release paper pass between the second pressing wheel 82 and the second conveying roller 83 to be subsequently processed by the staff. The second material pressing assembly 8 is matched with the winding roller to better realize the separation of waste materials and release paper.

Referring to fig. 6, in order to reduce the possibility that the second pressing wheel 82 slides on the second mounting shaft 81 and is displaced from the sponge to affect the pressing effect during operation, a second positioning member is disposed on the second pressing wheel 82. The second positioning member includes a second positioning ring 84 slidably fitted over the second mounting shaft 81, and a second positioning screw 85 threadedly coupled to a sidewall of the second positioning ring 84. The second positioning ring 84 is fixedly connected to the inner ring of the bearing on the second pressure wheel 82, and when the second positioning screw 85 is screwed, one end of the second positioning screw 85 abuts against the second mounting shaft 81, so that the position of the second pressure wheel 82 on the second mounting shaft 81 is fixed, and the rotation of the second pressure wheel 82 is not affected.

Referring to fig. 3, in order to reduce wear of the first nip wheel 721 and the second nip wheel 82 to the sponge, a rubber ring is sleeved on the outer circumferential walls of the first nip wheel 721 and the second nip wheel 82.

The implementation principle of the die-cutting machine capable of synchronously discharging waste is as follows: the coiled sponge is placed on the unreeling rack 1, and the distance between the limiting plates 34 is adjusted according to the width of the sponge. After the limiting plates 34 are moved to proper positions, the locking screw 332 is screwed down, the sliding sleeve 331 is fastened, the sponge passes through the supporting roller 32 and is positioned between the two limiting plates 34, and the pressing sheet 333 is pressed on the sponge. The sponge passes through the limiting block 38 and then passes through the die cutting machine, the die cutting machine performs die cutting on the sponge, and the die-cut sponge passes between the first pressing plate 361 and the first bottom plate 36. And passes between the first conveying roller 76 and the first nip wheel 721, and then passes through the pressing piece 731. The waste materials cut from the sponge bypass the guide rod 54 and are wound by the winding shaft 52, and the release paper and the products cut and formed from the release paper pass between the second conveying roller 83 and the second pressing wheel 82 and are subjected to subsequent treatment by workers.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a synchronous waste discharge's cross cutting machine, includes workstation (2), connects cross cutting machine body (4) on workstation (2), its characterized in that: still including connecting press device (6), receipts waste device (5) on workstation (2), press device (6) and receipts waste device (5) are located the one side of cross cutting machine body (4) ejection of compact, press device (6) including first press subassembly (7) that are used for compressing tightly sponge piece and waste material, second press subassembly (8) that are used for compressing tightly the sponge piece, receive waste device (5) including connecting support (51) on workstation (2), rotate wind-up shaft (52), the driving piece of transmission connection on wind-up shaft (52) on support (51).

2. The die cutting machine of synchronous waste discharge of claim 1, characterized in that: support (51) fixed connection is on workstation (2), rolling axle (52) rotate to be connected on the top of support (51), the axis perpendicular to defeated material direction of rolling axle (52), driving piece is driving motor (53) of fixed connection on support (51).

3. The die cutting machine of synchronous waste discharge of claim 1, characterized in that: first material pressing assembly (7) erect including second bottom plate (71), the level on second bottom plate (71) of connection, first installation axle (72), the slip cover that establishes on first installation axle (72) first material pressing wheel (721), the level erects pinch bar (73) on workstation (2), compact heap (731) of fixed connection on pinch bar (73), second bottom plate (71) are located the discharge side of cross cutting machine body (4), first installation axle (72) are defeated the material direction setting of perpendicular to, first material pressing wheel (721) laminating second bottom plate (71) set up, the length direction setting along pinch bar (73) of pinch bar (731).

4. The die cutting machine of claim 3, wherein: one side that second bottom plate (71) deviates from cross cutting machine body (4) is connected with arc (78) of downwarping, arc (78) are laminated to one side of compact heap (731), second swage subassembly (8) are established second swage wheel (82) on second installation axle (81) including second installation axle (81), the slip cover of horizontal connection on workstation (2).

5. The die cutting machine of synchronous waste discharge of claim 4, wherein: the first pressing wheel (721) is provided with a first positioning piece, and the second pressing wheel (82) is provided with a second positioning piece.

6. The die cutting machine of synchronous waste discharge of claim 1, characterized in that: one side of the feeding of the die cutting machine body (4) is provided with an unreeling frame (1) and a limiting device (3), and the limiting device (3) is positioned between the unreeling frame (1) and the die cutting machine body (4).

7. The die cutting machine of synchronous waste discharge of claim 6, characterized in that: stop device (3) establish limiting plate (34), horizontally connect installation pole (33) on support frame (31), the preforming (333) of connection on installation pole (33) on support roll (32) including support frame (31), the horizontal connection of connection on workstation (2) back-up roll (32), cover on support roll (31), back-up roll (32) perpendicular to defeated material direction sets up, limiting plate (34) are provided with two, installation pole (33) are located back-up roll (32) top, the one end that preforming (333) deviates from installation pole (33) is pressed on back-up roll (32).

8. The die cutting machine of synchronous waste discharge of claim 7, wherein: a horizontal first bottom plate (36) is arranged between the pressing plate (333) and the die cutting machine body (4), the first bottom plate (36) is fixedly connected onto the supporting frame (31), a horizontal first pressing plate (361) is arranged on the first bottom plate (36), and a gap is reserved between the first pressing plate (361) and the first bottom plate (36).

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