CN113147081A

CN113147081A - Cardboard die-cutting machine is used in carton production

Info

Publication number: CN113147081A
Application number: CN202110448943.0A
Authority: CN
Inventors: 魏国锋
Original assignee: Shaoxing China International Marine Containers Group Package Co ltd
Current assignee: Shaoxing China International Marine Containers Group Package Co ltd
Priority date: 2021-04-25
Filing date: 2021-04-25
Publication date: 2021-07-23

Abstract

The invention relates to the technical field of paperboard die-cutting machines, in particular to a paperboard die-cutting machine for carton production, which comprises a device main body, a motor, a connecting belt and a conveying roller, wherein the motor is arranged inside the device main body, an automatic material pushing mechanism is arranged on the right side of the device main body, an adjustable material storing mechanism is arranged at the top end of the device main body, and the automatic material pushing mechanism comprises a first belt pulley, a pushing bin, a driving belt, a second belt pulley, a first connecting shaft, a driving gear, a movable groove, a connecting plate, an inserting groove, an inserting block, a first sliding groove, a first rack, a sector gear, a second connecting shaft, a driven gear, a second rack, a connecting gear, a fixed shaft, a third rack, a top plate, a second sliding block and a second sliding groove. The invention solves the problems that most of the existing paperboard die-cutting machines need manual feeding to die-cut paperboards and most of the existing paperboard die-cutting machines do not have material storage structures and the problems.

Description

Cardboard die-cutting machine is used in carton production

Technical Field

The invention relates to the technical field of paperboard die-cutting machines, in particular to a paperboard die-cutting machine for producing cartons.

Background

The paper board die-cutting machine is a machine for die-cutting paper boards in a carton forming process, and generally comprises two die-cutting modes of flat pressing and circular pressing, the selection of the die-cutting process is usually determined by the complexity and the quantity of orders, each die-cutting process has respective advantages and suitable production orders, and for example, the circular pressing circular die-cutting machine is suitable for the production of large-size paper boards, such as large-sized cartons and large-sized corrugated trays, and large-scale orders; the flat-pressing flat-die cutting machine is more suitable for the production of complex die cutting tool layout and small-batch orders, can finish the precision which is lacked by a circular die cutting machine and the process advantages in the aspect of layout, but can not reach the level of the circular die cutting machine in the aspects of production speed and paperboard processing size, so that the existing paperboard die cutting machine basically meets the requirements of people, but still has some problems.

The first problem is that: the existing paperboard die-cutting machine mostly needs manual feeding to die-cut paperboards, is inconvenient to process the paperboards, consumes a large amount of manpower, reduces the working efficiency of the device, and is low in practicability and usability.

The second problem is that: the existing paperboard die-cutting machine mostly does not have a storage structure for materials, and the materials are frequently lifted by people and placed on the device when the materials are processed, so that the time and the labor are wasted, the practicability and the usability are low, and the paperboard die-cutting machine for carton production is urgently needed to solve the problems.

Disclosure of Invention

The invention aims to provide a paperboard die-cutting machine for producing cartons, which aims to solve the problems that most of the existing paperboard die-cutting machines in the background art need manual feeding to die-cut paperboards, and most of the existing paperboard die-cutting machines do not have a material storage structure and do not have the material storage structure.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a cardboard die-cutting machine for carton production, includes device main part, motor, connection belt and transfer roller, its characterized in that: the inside of device main part is provided with the motor, and the outside cover of motor output is equipped with one side of connecting the belt, the opposite side cover of connecting the belt is established in the outside of transfer roller, the right side of device main part is provided with automatic pushing equipment, and the top of device main part is provided with adjustable storage mechanism.

Preferably, the automatic material pushing mechanism comprises a first belt pulley, a pushing bin, a transmission belt, a second belt pulley, a first connecting shaft, a driving gear, a movable groove, a connecting plate, an inserting groove, an inserting block, a first slider, a first sliding groove, a first rack, a sector gear, a second connecting shaft, a driven gear, a second rack, a connecting gear, a fixed shaft, a third rack, a top plate, a second slider and a second sliding groove, the left side of the device body is fixedly connected with the pushing bin, the transmission roller is fixedly provided with the first belt pulley, the outer side of the first belt pulley is sleeved with one side of the transmission belt, the other side of the transmission belt is sleeved on the outer side of the second belt pulley, the second belt pulley is fixedly arranged on the first connecting shaft, one end of the first connecting shaft is movably connected to the position close to one side inside the pushing bin through a bearing, and the central position of the first connecting shaft is fixedly provided with the driving gear, the two ends of the driving gear are respectively engaged with a driven gear, the driven gear is fixedly arranged on a second connecting shaft, one end of the second connecting shaft is movably connected to one side inside the pushing bin through a bearing, the other end of the second connecting shaft is fixedly provided with a sector gear, the sector gear is engaged with a first rack, the first rack is fixedly arranged on one side of a connecting plate, the two ends of one side of the connecting plate are respectively fixedly provided with a first rack, the other end of the first connecting shaft is slidably connected inside a movable groove, the movable groove is arranged on one side inside the connecting plate, the top end of the other side of the connecting plate is fixedly connected with a second rack, the second rack is engaged with one end of the connecting gear, the central position of the connecting gear is fixedly connected with a fixed shaft, and one end of the fixed shaft is movably connected to the other side inside the pushing bin through a bearing, the other end meshing of connecting gear has the third rack, and third rack fixed mounting is in the roof bottom be close to central point and put the department, the roof top is close to the equal fixedly connected with second slider in the position department of both sides, and second slider sliding connection is in the inside of second spout, the second spout is seted up in one side on propelling movement storehouse top.

Preferably, the adjustable material storage mechanism comprises a fixed sleeve, a sleeve groove, a movable sleeve, a connecting block, a sliding groove, a threaded sleeve, a screw rod, a movable cavity, an adjusting bin, a first bevel gear, a second bevel gear, a connecting rod, a rotating handle, an adjusting cavity, a supporting plate, a discharging port, a material pushing port, a third sliding block and a third sliding groove, wherein the fixed sleeve is fixedly connected to the right side of the top end of the device body, the sleeve grooves are formed in the two sides of the fixed sleeve, the movable sleeve is sleeved in the sleeve groove, one side of the connecting block is fixedly connected to one side of the bottom end of the movable sleeve, the connecting block is slidably connected to the inside of the sliding groove, the sliding groove is formed in the right side of the fixed sleeve, the other side of the connecting block is fixedly connected with the threaded sleeve, the threaded sleeve is connected to the outer side of the screw rod, the two ends of the screw rod, adjusting the right side of storehouse fixed mounting at fixed cover, the bottom of screw rod pierces through the inside that the movable chamber extends to the regulation chamber, and adjusts the chamber and set up in the bottom in movable chamber, the first conical gear of bottom fixedly connected with of screw rod, and first conical gear and second conical gear meshing, second conical gear fixed mounting is in one side of connecting rod, and the connecting rod passes through bearing swing joint in the inside of adjusting the chamber, the inside of fixed cover is provided with the backup pad.

Preferably, slots are formed in the two ends of the connecting plate, and the inserting blocks are inserted in the slots.

Preferably, the other side of the bottom end of the sleeve groove is fixedly connected with a third sliding block, the third sliding block is connected to the inside of a third sliding groove in a sliding mode, and the third sliding groove is formed in one side of the inside of the sleeve groove.

Preferably, the other side of the connecting rod penetrates through the adjusting bin and extends to the outer side of the adjusting bin, and the other side of the connecting rod is fixedly connected with a rotating handle.

Preferably, the outer side of the rotating handle is wrapped with a rubber sleeve, and the outer side of the rubber sleeve is provided with anti-skid grains.

Preferably, the support plate is fixedly connected to the inner side of the fixed sleeve at a position close to the bottom end, and the bottom end of the right side of the fixed sleeve is provided with a material pushing opening.

Preferably, the inserting block is fixedly connected to the other side of the inside of the pushing bin, a first sliding block is fixedly mounted on the inserting block and is connected to the inside of the first sliding groove in a sliding mode, and the first sliding groove is formed in one end of the inside of the slot.

Compared with the prior art, the invention has the beneficial effects that:

1. the paperboard die-cutting machine for producing the cartons is provided with an automatic material pushing mechanism, a first belt pulley, a pushing bin, a transmission belt, a second belt pulley, a first connecting shaft, a driving gear, a movable groove, a connecting plate, an inserting groove, an inserting block, a first sliding groove, a first rack, a sector gear, a second connecting shaft, a driven gear, a second rack, a connecting gear, a fixed shaft, a third rack, a top plate, a second sliding block and a second sliding groove are used for automatically pushing materials to perform die-cutting processing on the materials, manpower is saved, a person is not required to manually push a material entering device to process the materials, the practicability and the usability are enhanced, when the device is started, a motor is also started, the transmission roller is driven to rotate by the connecting belt, the first belt pulley is driven to rotate by the rotation of the connecting belt, the transmission belt sleeved on the outer side of the first belt pulley is driven to rotate by the rotation of the first belt pulley, meanwhile, the first connecting shaft is driven to rotate along with the first connecting shaft under the action of the transmission belt and the second belt pulley, the first connecting shaft drives a driving gear fixedly connected with the first connecting shaft to rotate, the driving gear drives two groups of driven gears meshed with the driving gear to rotate along with the driving gear, sector gears which are connected to the second connecting shaft and are also connected with the driven gears to rotate along with the driven gears, the sector gears drive a first rack meshed with the sector gears to move, the connecting plate moves along with the sector gears, the connecting plate is driven to reciprocate under the action of the two groups of sector gears, the connecting plate drives a connecting gear meshed with the sector gears to rotate under the action of a second rack fixedly arranged on the connecting plate when moving, the connecting gear rotates to drive a third rack to move, and a top plate fixedly connected with the third rack moves along with the second rack to eject the lowest layer of materials in the fixing sleeve, then the connecting gear is driven to rotate reversely under the action of the reciprocating motion of the connecting plate, the top plate is driven to return to the original position, the material in the fixed sleeve falls, and then the step is repeated to eject the material, so that the problem that most of the existing paperboard die-cutting machines need manual feeding to die-cut the paperboard is solved;

2. the paperboard die cutting machine for producing the cartons is provided with an adjustable storage mechanism, materials are stored through a fixed sleeve, a sleeve groove, a movable sleeve, a connecting block, a sliding groove, a threaded sleeve, a screw rod, a movable cavity, an adjusting bin, a first bevel gear, a second bevel gear, a connecting rod, a rotating handle, an adjusting cavity, a supporting plate, a discharging port, a pushing port, a third sliding block and a third sliding groove, the materials are prevented from being repeatedly carried by an operator, the height of the adjustable storage mechanism can be adjusted at the same time, more materials can be stored in the adjustable storage mechanism, the practicability and the usability are improved, when the height of the adjustable storage mechanism is adjusted, the rotating handle is firstly rotated to drive the second bevel gear to rotate, the second bevel gear rotates to drive the first bevel gear meshed with the second bevel gear to rotate, the screw rod fixedly connected with the second bevel gear rotates to drive the threaded sleeve to move, the screw sleeve moves to drive the movable sleeve to move so as to adjust the height of the adjustable material storage mechanism, and the problem that the conventional paperboard die-cutting machine does not have a material storage structure and cannot store materials is solved.

Drawings

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

FIG. 2 is a schematic view of a partial front cross-sectional structure of the present invention;

FIG. 3 is an enlarged view of the structure at A in FIG. 2 according to the present invention;

FIG. 4 is an enlarged view of the structure at B in FIG. 3 according to the present invention;

FIG. 5 is an enlarged view of the structure at C of FIG. 2 according to the present invention;

FIG. 6 is an enlarged view of the structure of FIG. 2;

FIG. 7 is a schematic view of a partial rear view cross-sectional structure of the present invention;

FIG. 8 is a schematic view of a partial back-view cross-sectional structure of the automatic pushing mechanism of the present invention;

FIG. 9 is a schematic diagram of a partial side view of the automatic pushing mechanism according to the present invention;

FIG. 10 is an enlarged view of the structure at E in FIG. 9 according to the present invention;

fig. 11 is an enlarged view of the structure at F in fig. 9 according to the present invention.

In the figure: 1. a device main body; 2. a motor; 3. connecting a belt; 4. a conveying roller; 51. a first pulley; 52. a pushing bin; 53. a drive belt; 54. a second pulley; 55. a first connecting shaft; 56. a driving gear; 57. a movable groove; 58. a connecting plate; 59. a slot; 510. inserting a block; 511. a first slider; 512. a first chute; 513. a first rack; 514. a sector gear; 515. a second connecting shaft; 516. a driven gear; 517. a second rack; 518. a connecting gear; 519. a fixed shaft; 520. a third rack; 521. a top plate; 522. a second slider; 523. a second chute; 61. fixing a sleeve; 62. sleeving a groove; 63. a movable sleeve; 64. connecting blocks; 65. a sliding groove; 66. a threaded sleeve; 67. a screw; 68. a movable cavity; 69. a regulating bin; 610. a first bevel gear; 611. a second bevel gear; 612. a connecting rod; 613. rotating the handle; 614. an adjustment chamber; 615. a support plate; 616. a discharge port; 617. pushing a material port; 618. a third slider; 619. and a third chute.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-11, an embodiment of the present invention: a paperboard die cutting machine for carton production comprises a device main body 1, a motor 2, a connecting belt 3 and a conveying roller 4, wherein the motor 2 is arranged inside the device main body 1, and the outer side of the output end of the motor 2 is sleeved with one side of a connecting belt 3, the other side of the connecting belt 3 is sleeved with the outer side of the conveying roller 4, the right side of the device main body 1 is provided with an automatic material pushing mechanism, the top end of the device main body 1 is provided with an adjustable material storing mechanism, the processing efficiency of the device is greatly improved through the automatic material pushing mechanism and the adjustable material storing mechanism, the working intensity of operators is reduced, the automatic material pushing mechanism automatically pushes the materials, so that the materials fall on the device to process the materials without manual pushing one by one, the materials to be processed are stored through the adjustable storage mechanism, so that the situation that the operators carry the materials repeatedly is avoided.

The automatic material pushing mechanism comprises a first belt pulley 51, a pushing bin 52, a transmission belt 53, a second belt pulley 54, a first connecting shaft 55, a driving gear 56, a movable groove 57, a connecting plate 58, an inserting groove 59, an inserting block 510, a first sliding block 511, a first sliding groove 512, a first rack 513, a sector gear 514, a second connecting shaft 515, a driven gear 516, a second rack 517, a connecting gear 518, a fixed shaft 519, a third rack 520, a top plate 521, a second sliding block 522 and a second sliding groove 523, the left side of the device main body 1 is fixedly connected with the pushing bin 52, the transmission roller 4 is fixedly provided with the first belt pulley 51, the outer side of the first belt pulley 51 is sleeved with one side of the transmission belt 53, the other side of the transmission belt 53 is sleeved with the outer side of the second belt pulley 54, the second belt pulley 54 is fixedly arranged on the first connecting shaft 55, one end of the first connecting shaft 55 is movably connected to a position close to the center of one side inside the pushing bin 52, a driving gear 56 is fixedly arranged at the central position of the first connecting shaft 55, two ends of the driving gear 56 are engaged with a driven gear 516, the driven gear 516 is fixedly arranged on a second connecting shaft 515, one end of the second connecting shaft 515 is movably connected to one side inside the pushing bin 52 through a bearing, the other end of the second connecting shaft 515 is fixedly provided with a sector gear 514, the sector gear 514 is engaged with a first rack 513, the first rack 513 is fixedly arranged at one side of a connecting plate 58, two ends of one side of the connecting plate 58 are fixedly provided with a first rack 513, the other end of the first connecting shaft 55 is slidably connected inside a movable groove 57, the movable groove 57 is arranged at one side inside the connecting plate 58, the top end of the other side of the connecting plate 58 is fixedly connected with a second rack 517, the second rack 517 is engaged with one end of a connecting gear 518, and a fixed shaft 519 is fixedly connected at the central position of the connecting gear 518, one end of the fixed shaft 519 is movably connected to the other side inside the pushing bin 52 through a bearing, the other end of the connecting gear 518 is meshed with a third rack 520, the third rack 520 is fixedly installed at the position, close to the center, of the bottom end of the top plate 521, the positions, close to the two sides, of the top end of the top plate 521 are fixedly connected with second sliding blocks 522, the second sliding blocks 522 are connected inside second sliding grooves 523 in a sliding mode, the second sliding grooves 523 are arranged on one side of the top end of the pushing bin 52, the existing motor 2, the connecting belt 3, the conveying roller 4 and the like are all the prior art, the working principle, the technical principle, the related structures, the specific connection relations, the circuit relations and the like among the structures are transparent for ordinary technicians in the field, the automatic material pushing mechanism plays a role of automatically pushing materials to the device to process logistics, and a large amount of labor force is saved, the materials are processed on the device without manually putting the materials one by one, the practicability and the usability are improved compared with the existing device, and the processing efficiency of the materials is improved.

The adjustable material storage mechanism comprises a fixed sleeve 61, a sleeve groove 62, a movable sleeve 63, a connecting block 64, a sliding groove 65, a threaded sleeve 66, a screw 67, a movable cavity 68, an adjusting bin 69, a first bevel gear 610, a second bevel gear 611, a connecting rod 612, a rotating handle 613, an adjusting cavity 614, a supporting plate 615, a material outlet 616, a material pushing port 617, a third sliding block 618 and a third sliding groove 619, wherein the right side of the top end of the device main body 1 is fixedly connected with the fixed sleeve 61, the sleeve grooves 62 are respectively arranged inside two sides of the fixed sleeve 61, the movable sleeve 63 is sleeved inside the sleeve groove 62, one side of the bottom end of the movable sleeve 63 is fixedly connected with one side of the connecting block 64, the connecting block 64 is slidably connected inside the sliding groove 65, the sliding groove 65 is arranged on the right side of the fixed sleeve 61, the other side of the connecting block 64 is fixedly connected with the threaded sleeve 66, the threaded sleeve 66 is connected outside the screw 67, two ends of the screw 67 are movably connected inside the movable cavity 68 through bearings, the movable cavity 68 is arranged inside the adjusting cavity 69, the adjusting cavity 69 is fixedly arranged on the right side of the fixed sleeve 61, the bottom end of the screw 67 penetrates through the movable cavity 68 and extends to the inside of the adjusting cavity 614, the adjusting cavity 614 is arranged at the bottom end of the movable cavity 68, the bottom end of the screw 67 is fixedly connected with a first bevel gear 610, the first bevel gear 610 is meshed with a second bevel gear 611, the second bevel gear 611 is fixedly arranged on one side of the connecting rod 612, the connecting rod 612 is movably connected inside the adjusting cavity 614 through a bearing, a supporting plate 615 is arranged inside the fixed sleeve 61, the adjustable material storage mechanism is used for storing materials, the situation that operators carry the materials repeatedly is avoided, and the working strength of the operators is reduced.

The slots 59 are formed in the two ends of the connecting plate 58, the inserting blocks 510 are inserted into the slots 59, the connecting plate 58 is positioned through the slots 59 and the inserting blocks 510, and the connecting plate is prevented from shaking when moving.

The opposite side fixedly connected with third slider 618 of cover 62 bottom, and third slider 618 sliding connection is in the inside of third spout 619, and third spout 619 sets up in the inside one side of cover 62, plays the effect that makes the movable sleeve 63 more smooth and easy when removing through third slider 618 and third spout 619, prevents that the movable sleeve 63 from blocking when removing.

The other side of the connecting rod 612 penetrates through the adjusting cabin 69 and extends to the outer side of the adjusting cabin 69, the other side of the connecting rod 612 is fixedly connected with a rotating handle 613, and the rotating handle 613 is arranged to play a more convenient role in rotating the connecting rod 612.

The outer side of the rotating handle 613 is covered with a rubber sleeve, and the outer side of the rubber sleeve is provided with anti-slip threads, so that the anti-slip function of the rotating handle 613 can be achieved by the rubber sleeve covered on the outer side of the rotating handle 613 and the anti-slip threads arranged on the outer side of the rubber sleeve.

Backup pad 615 fixed connection is in the inboard position department that is close to the bottom of fixed cover 61, and the right side bottom of fixed cover 61 has been seted up and has been pushed away material mouth 617, thereby makes roof 521 can promote the material and fall to the device through seting up and push away material mouth 617 on, processes the material.

The inserting block 510 is fixedly connected to the other side of the interior of the pushing bin 52, the first sliding block 511 is fixedly mounted on the inserting block 510, the first sliding block 511 is connected to the interior of the first sliding groove 512 in a sliding mode, the first sliding groove 512 is formed in one end of the interior of the slot 59, the first sliding block 511 and the first sliding groove 512 play a role in enabling the connecting plate 58 to move more smoothly, and the connecting plate 58 is prevented from being clamped due to overlarge friction force when moving.

The working principle is as follows: when the device is started, the motor 2 is started, the conveying roller 4 is driven to rotate by the connecting belt 3, the connecting belt 3 drives the first belt pulley 51 to rotate, the first belt pulley 51 drives the transmission belt 53 sleeved on the outer side of the first belt pulley to rotate, meanwhile, the first connecting shaft 55 is driven to rotate by the action of the transmission belt 53 and the second belt pulley 54, the first connecting shaft 55 rotates to drive the driving gear 56 fixedly connected with the first connecting shaft to rotate, the driving gear 56 rotates to drive the two groups of driven gears 516 meshed with the driving gear to rotate, the sector gear 514 connected to the second connecting shaft 515 like the driven gear 516 rotates, the sector gear 514 rotates to drive the first rack 513 meshed with the sector gear to move, the connecting plate 58 moves along with the sector gear, and the connecting plate 58 is driven to reciprocate by the action of the two groups of sector gears 514, when the connecting plate 58 moves, the second rack 517 fixedly mounted on the connecting plate 58 drives the connecting gear 518 engaged with the connecting plate to rotate, the connecting gear 518 rotates to drive the third rack 520 to move, meanwhile, the top plate 521 fixedly connected with the third rack 520 also moves to eject the lowest material in the fixing sleeve 61, then the connecting gear 518 is driven to rotate reversely under the reciprocating motion of the connecting plate 58 to drive the top plate 521 to return to the original position, so that the material in the fixing sleeve 61 falls down, and then the step is repeated to eject the material.

When the height of the adjustable material storage mechanism is to be adjusted, firstly, the rotating handle 613 is rotated to drive the second bevel gear 611 to rotate, the second bevel gear 611 rotates to drive the first bevel gear 610 engaged with the second bevel gear 611 to rotate, the screw 67 fixedly connected with the second bevel gear 611 also rotates to drive the threaded sleeve 66 to move, and the threaded sleeve 66 moves to drive the movable sleeve 63 to move to adjust the height of the adjustable material storage mechanism.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides a cardboard die-cutting machine for carton production, includes device main part (1), motor (2), connecting belt (3) and transfer roller (4), its characterized in that: the inside of device main part (1) is provided with motor (2), and the outside cover of motor (2) output is equipped with one side of connecting belt (3), the opposite side cover of connecting belt (3) is established in the outside of transfer roller (4), the right side of device main part (1) is provided with automatic pushing equipment, and the top of device main part (1) is provided with adjustable storage mechanism.

2. The carton board die cutting machine for producing cartons as claimed in claim 1, wherein: the automatic material pushing mechanism comprises a first belt pulley (51), a pushing bin (52), a transmission belt (53), a second belt pulley (54), a first connecting shaft (55), a driving gear (56), a movable groove (57), a connecting plate (58), an inserting groove (59), an inserting block (510), a first sliding block (511), a first sliding groove (512), a first rack (513), a sector gear (514), a second connecting shaft (515), a driven gear (516), a second rack (517), a connecting gear (518), a fixed shaft (519), a third rack (520), a top plate (521), a second sliding block (522) and a second sliding groove (523), the pushing bin (52) is fixedly connected to the left side of the device main body (1), the transmission roller (4) is fixedly provided with the first belt pulley (51), and one side of the transmission belt (53) is sleeved on the outer side of the first belt pulley (51), the other side of the transmission belt (53) is sleeved on the outer side of the second belt pulley (54), the second belt pulley (54) is fixedly installed on the first connecting shaft (55), one end of the first connecting shaft (55) is movably connected to one side inside the pushing bin (52) through a bearing and is close to the central position, a driving gear (56) is fixedly installed at the central position of the first connecting shaft (55), both ends of the driving gear (56) are respectively meshed with a driven gear (516), the driven gear (516) is fixedly installed on the second connecting shaft (515), one end of the second connecting shaft (515) is movably connected to one side inside the pushing bin (52) through a bearing, a sector gear (514) is fixedly installed at the other end of the second connecting shaft (515), the sector gear (514) is meshed with the first rack (513), and the first rack (513) is fixedly installed on one side of the connecting plate (58), the two ends of one side of the connecting plate (58) are fixedly provided with first racks (513), the other end of the first connecting shaft (55) is connected inside the movable groove (57) in a sliding manner, the movable groove (57) is formed in one side of the inside of the connecting plate (58), the top end of the other side of the connecting plate (58) is fixedly connected with a second rack (517), the second rack (517) is meshed with one end of the connecting gear (518), the central position of the connecting gear (518) is fixedly connected with a fixing shaft (519), one end of the fixing shaft (519) is movably connected to the other side of the inside of the pushing bin (52) through a bearing, the other end of the connecting gear (518) is meshed with a third rack (520), the third rack (520) is fixedly arranged at the position, close to the central position, of the bottom end of the top plate (521), close to the two sides, of the top end of the top plate (521) is fixedly connected with second sliding blocks (522), and the second sliding block (522) is connected inside the second sliding chute (523) in a sliding manner, and the second sliding chute (523) is arranged on one side of the top end of the pushing bin (52).

3. The carton board die cutting machine for producing cartons as claimed in claim 1, wherein: the adjustable material storage mechanism comprises a fixed sleeve (61), a sleeve groove (62), a movable sleeve (63), a connecting block (64), a sliding groove (65), a threaded sleeve (66), a screw rod (67), a movable cavity (68), an adjusting bin (69), a first bevel gear (610), a second bevel gear (611), a connecting rod (612), a rotating handle (613), an adjusting cavity (614), a supporting plate (615), a discharge hole (616), a material pushing hole (617), a third sliding block (618) and a third sliding groove (619), wherein the right side of the top end of the device main body (1) is fixedly connected with the fixed sleeve (61), the sleeve grooves (62) are formed in the two sides of the fixed sleeve (61), the movable sleeve (63) is sleeved in the sleeve groove (62), one side of the bottom end of the movable sleeve (63) is fixedly connected with one side of the connecting block (64), and the connecting block (64) is slidably connected in the sliding groove (65), the right side at fixed cover (61) is seted up in sliding tray (65), the opposite side and swivel nut (66) fixed connection of connecting block (64), and swivel nut (66) threaded connection is in the outside of screw rod (67), the both ends of screw rod (67) are all through the inside of bearing swing joint in activity chamber (68), and the inside in regulation storehouse (69) is seted up in activity chamber (68), adjust storehouse (69) fixed mounting on the right side of fixed cover (61), the bottom of screw rod (67) pierces through activity chamber (68) and extends to the inside in regulation chamber (614), and adjusts chamber (614) and sets up in the bottom in activity chamber (68), the bottom fixed connection of screw rod (67) has first conical gear (610), and first conical gear (610) and second conical gear (611) meshing, second conical gear (611) fixed mounting is in one side of connecting rod (612), and the connecting rod (612) is movably connected inside the adjusting cavity (614) through a bearing, and a supporting plate (615) is arranged inside the fixed sleeve (61).

4. The carton board die cutting machine for producing cartons as claimed in claim 2, wherein: slots (59) are formed in the two ends of the connecting plate (58), and inserting blocks (510) are inserted into the slots (59).

5. The carton board die cutting machine for producing cartons as claimed in claim 3, wherein: the opposite side fixedly connected with third slider (618) of cover groove (62) bottom, and third slider (618) sliding connection is in the inside of third spout (619), one side in cover groove (62) inside is seted up in third spout (619).

6. The carton board die cutting machine for producing cartons as claimed in claim 3, wherein: the other side of the connecting rod (612) penetrates through the adjusting bin (69) and extends to the outer side of the adjusting bin (69), and the other side of the connecting rod (612) is fixedly connected with a rotating handle (613).

7. The carton board die cutting machine for producing cartons as claimed in claim 6, wherein: the outer side of the rotating handle (613) is wrapped with a rubber sleeve, and the outer side of the rubber sleeve is provided with anti-slip threads.

8. The carton board die cutting machine for producing cartons as claimed in claim 3, wherein: backup pad (615) fixed connection is in the position department that fixed cover (61) inboard is close to the bottom, and the right side bottom of fixed cover (61) has seted up and has pushed away material mouth (617).

9. The carton board die cutting machine for producing cartons as claimed in claim 4, wherein: insert piece (510) fixed connection is at the inside opposite side in propelling movement storehouse (52), fixed mounting has first slider (511) on insert piece (510), and first slider (511) sliding connection is in the inside of first spout (512), the one end in slot (59) inside is seted up in first spout (512).