CN219523193U - Full-automatic adjustable paperboard grooving machine - Google Patents

Abstract

The utility model relates to a full-automatic adjustable paperboard grooving machine which is convenient to adjust to adapt to paperboards with different specifications. The full-automatic adjustable paperboard grooving machine comprises a frame, a paper feeding conveying mechanism, a paperboard correcting mechanism and a paperboard grooving mechanism; the paperboard deviation correcting mechanism comprises a deviation correcting backup plate; the paper board grooving mechanism comprises a grooving cutter, a grooving roller, a belt and a belt roller, and is characterized in that: a cutter adjusting guide rail parallel to the roll shaft of the grooving roller is arranged on the frame, a cutter sliding seat is arranged on the cutter adjusting guide rail in a sliding manner, and the grooving cutter is arranged on the cutter sliding seat; the machine frame is provided with a cutter adjusting mechanism and a belt adjusting mechanism. The full-automatic adjustable paperboard grooving machine can realize automatic belt adjustment and automatic grooving cutter adjustment, thereby greatly reducing the overall machine adjustment difficulty and rapidly meeting the grooving requirements of paperboards with different specifications.

Description

Full-automatic adjustable paperboard grooving machine

Technical Field

The utility model relates to a paperboard grooving machine.

Background

Generally, paper packaging containers such as cartons and cartons are formed by folding a paperboard with grooves along the grooves, and a paperboard grooving machine is a device for grooving the paperboard. The general paper board groover is including paper board conveying mechanism, paper board rectifying mechanism and paper board grooving mechanism, grooving mechanism is including fluting cutter, fluting roller, belt and a plurality of belt roller, the belt winds on a plurality of belt rollers, belt part is pressed on the fluting roller under the effect of a plurality of belt rollers, the paper board is carried over on paper board conveying mechanism, then enter into between belt and the fluting roller, the bending laminating of paper board just is on the fluting roller under the effect of belt like this, the fluting roller rotates under the drive of power supply, drive paper board and belt rotate together, and the fluting cutter is located fluting roller one side, along with the removal of paper board, the fluting cutter just opens the groove on the paper board. However, the cardboard has different specifications, when the cardboard of different specifications needs processing, need adjust the position of rectifying mechanism, belt and fluting cutter, current belt is adjusted and is needed the workman to carry out manual removal according to the specification of cardboard, the fluting position is adjusted, because the change of cardboard specification, need adjust the too many of number of fluting cutter and belt, and the inside space limitation of machine has increased the degree of difficulty of adjusting fluting cutter and belt, the specification and the kind trend of present market cardboard are diversified, excessive debugging time has intangibly increased operator's intensity of labour and has reduced the production efficiency of complete machine.

Disclosure of Invention

In view of the shortcomings of the prior art, the utility model innovatively provides a full-automatic adjustable paperboard grooving machine which is convenient to adjust to adapt to paperboards with different specifications.

The full-automatic adjustable paperboard grooving machine comprises a frame, a paper feeding conveying mechanism, a paperboard correcting mechanism and a paperboard grooving mechanism; the paperboard deviation correcting mechanism comprises a deviation correcting backup plate; the paper board grooving mechanism comprises a grooving cutter, a grooving roller, a belt and a belt roller, and is characterized in that: a cutter guide rail parallel to the roll shaft of the grooving roller is arranged on the frame, a cutter sliding seat is arranged on the cutter guide rail in a sliding manner, and the grooving cutter is arranged on the cutter sliding seat; the machine frame is provided with a cutter adjusting mechanism, the cutter adjusting mechanism comprises a cutter adjusting power source, a cutter adjusting guide rail, a cutter adjusting seat, a bolt power source and a bolt, the cutter adjusting seat is arranged on the cutter adjusting guide rail in a sliding mode, the bolt power source can drive the cutter adjusting seat to move on the cutter adjusting guide rail, the bolt power source is arranged on the cutter adjusting seat, and the bolt power source can drive the bolt to act on the cutter sliding seat; an adjusting sliding rail is arranged on the frame, a moving wheel assembly is arranged on the adjusting sliding rail, the moving wheel assembly comprises a driven wheel and a moving sliding seat, the belt is wound on the driven wheel, the driven wheel is connected to the moving sliding seat, and the moving sliding seat is slidably arranged on the adjusting sliding rail; the belt adjusting mechanism comprises a belt adjusting guide rail, a belt adjusting slide seat, a belt adjusting power source, a shifting block and a shifting block power source, wherein the shifting block power source is arranged on the belt adjusting slide seat, the belt adjusting slide seat is slidably arranged on the belt adjusting guide rail, the belt adjusting power source can drive the belt adjusting slide seat to move on the belt adjusting guide rail, and the shifting block power source can drive the shifting block to act on the moving slide seat.

The paperboard deviation correcting mechanism is arranged on the movable seat, and the movable seat is slidably and adjustably arranged on the transverse guide rail; the deviation correcting backup plate can be horizontally rotated and adjusted through a pin shaft.

The guide rail seat is arranged on the movable seat, a linear guide rail which transversely extends is arranged on the guide rail seat, an adjusting slide block is arranged on the linear guide rail in a sliding mode, the adjusting slide block is connected with a rotary adjusting nut, the rotary adjusting nut is in threaded connection with a rotary adjusting screw rod, a lower guide rail which longitudinally extends is connected to the deviation correcting backup plate, a lower sliding seat is arranged on the lower guide rail in a sliding mode, and the lower sliding seat is connected with the rotary adjusting nut.

The rotary adjusting screw rod is in transmission connection with a rotary adjusting power source; the movable seat is in transmission connection with a transverse adjusting power source for driving the movable seat to move on the transverse guide rail.

The movable seat is connected with a transverse adjusting nut, the transverse adjusting nut is connected to the transverse adjusting screw rod in a threaded mode, and the transverse adjusting power source is connected with the transverse adjusting screw rod in a transmission mode.

The paper feeding and conveying mechanism is arranged on the movable seat and comprises a conveying belt or a conveying roller.

The grooving cutter is arranged on the cutter bar seat, the cutter bar seat is slidably arranged on the cutter slide seat, a cutter power source for driving the cutter bar seat to slide is arranged on the cutter slide seat, a positioning column capable of moving up and down is arranged on the cutter slide seat, and an action inclined plane capable of acting on the positioning column and enabling the positioning column to move downwards is arranged on the cutter bar seat.

The positioning column comprises a main column and an action column, wherein the action column is sleeved at the lower part of the main column in a vertically movable manner, and a spring is arranged between the main column and the action column.

The movable sliding seat is connected with a fastening screw in a threaded manner, and the fastening screw can act on the adjusting sliding rail.

The belt adjusting power source is in transmission connection with the belt adjusting screw rod, and the belt adjusting sliding seat is in threaded connection with the belt adjusting screw rod.

The adjusting slide rail is provided with two groups of parallel adjusting slide rails, each group of adjusting slide rail is provided with a moving wheel assembly, and each group of adjusting slide rail corresponds to one shifting block.

The movable sliding seat is provided with a positioning pin hole, and the shifting block power source can drive the shifting block to be inserted into the positioning pin hole of the movable sliding seat.

According to the full-automatic adjustable paperboard grooving machine provided by the utility model, automatic belt adjustment and automatic grooving cutter adjustment can be realized, so that the adjustment difficulty of the whole machine is greatly reduced, and the grooving requirements of paperboards with different specifications are rapidly met.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a cross-sectional view of the present utility model;

FIG. 3 is an enlarged view of a portion of FIG. 2;

FIG. 4 is a partial schematic view of the present utility model;

FIG. 5 is a perspective view of the present utility model;

FIG. 6 is a partial schematic view of a slotting cutter and screw portion;

FIG. 7 is a schematic structural view of a slotting cutter;

FIG. 8 is a cross-sectional view taken along the line A-A in FIG. 7;

FIG. 9 is a schematic illustration of portions of the paper feed transport mechanism and the cardboard correction mechanism;

FIG. 10 is a schematic view of a portion of the cardboard deviation correcting mechanism;

FIG. 11 is a schematic structural view of a paper feed conveying mechanism portion;

FIG. 12 is a schematic diagram of a prior art deviation correcting device with a beveled side edge;

fig. 13 is a schematic diagram of the deviation rectifying principle that the side edge of the paperboard is the bevel edge after the deviation rectifying backup plate is adjusted.

Detailed Description

As shown in fig. 1 and 2, the full-automatic adjustable paperboard grooving machine comprises a frame 1, a paper feeding and conveying mechanism 2, a paperboard deviation correcting mechanism 3 and a paperboard grooving mechanism 4; the paperboard deviation correcting mechanism 3 comprises a deviation correcting backup plate 31; the board grooving mechanism 4 includes a grooving cutter 43, a grooving roller 42, a belt 45, and a belt roller 44, and the belt 45 acts on the grooving roller 42 under the guidance and tension of the belt roller 44. When the paper feeding device works, the paper board B is conveyed on the paper feeding conveying mechanism 2 and then enters between the belt 45 and the grooving roller 42, so that the paper board B is bent and attached to the grooving roller 42 under the action of the belt 45, the grooving roller 42 is driven by a power source to rotate, the paper board B is driven to rotate together with the belt 45, the grooving cutter 43 is positioned on one side of the grooving roller 42, and along with the movement of the paper board B, the grooving cutter 43 opens a groove on the paper board B.

In order to adjust the position of the belt 45, as shown in fig. 3 and 4, an adjusting slide rail 48 is mounted on the frame 1, a moving wheel assembly is mounted on the adjusting slide rail 48, the moving wheel assembly comprises a driven wheel 46 and a moving slide seat 47, the belt 45 is wound on the driven wheel 46, the driven wheel 46 is connected to the moving slide seat 47, the moving slide seat 47 is slidably arranged on the adjusting slide rail 48, and thus, the left and right positions of the belt 45 can be adjusted only by moving the moving slide seat 47; in order to move the movable slide 47, a belt adjusting mechanism 5 is arranged on the frame 1, the belt adjusting mechanism 5 comprises a belt adjusting guide rail 50, a belt adjusting slide seat 51, a belt adjusting power source, a shifting block 53 and a shifting block power source 52, the shifting block power source 52 is arranged on the belt adjusting slide seat 51, the belt adjusting slide seat 51 is arranged on the belt adjusting guide rail 50 in a sliding manner, the belt adjusting power source can drive the belt adjusting slide seat 51 to move on the belt adjusting guide rail 50, and the shifting block 53 can be driven by the shifting block power source 52 to act on the movable slide 47.

The belt 45 adjustment principle is as follows: when adjusting belts are needed for processing paperboards with different specifications, the shifting block power source 52 drives the shifting block 53 to act on the moving slide seat 47, so that the shifting block 53 and the moving slide seat 47 form locking relation, then the adjusting belt power source drives the adjusting belt slide seat 51 to move on the adjusting belt guide rail 50, and the shifting block 53 and the shifting block power source 52 are arranged on the adjusting belt slide seat 51, so that the adjusting belt slide seat 51 drives the moving slide seat 47 to move on the adjusting slide rail 48. Of course, during the adjustment process, the belt 45 is still in a tightening state, and both the belt 45 and the grooved roll 42 are in a rotating state, when the adjustment end of the belt 45 is displaced due to the adjustment, the whole belt 45 can incline in the front-rear direction, but due to the tightening and rotating state of the belt 45, the belt 45 can automatically correct the position along with one rotation of the belt 45, so that the front-rear direction of the belt 45 returns to a straight line perpendicular to the axle center of the grooved roll 42. In this way, the belt 45 is not required to be loosened for adjustment, and the adjustment can be performed only by inputting parameters to the belt adjusting power source, so that the adjustment is very convenient and quick.

The shifting block 53 may directly act on the movable slide 47 in locking relation (face-to-face contact, locking relation by friction force), but the locking force may not be sufficient, and in order to form a sufficiently strong locking force, the present utility model provides a positioning pin hole 470 in the movable slide 47, and the shifting block power source 52 may drive the shifting block 53 to be inserted into the positioning pin hole 470 of the movable slide 47. With this structure, it is ensured that the dial 53 stably drives the moving slide 47 to move.

In order to accurately adjust the position of the belt 45, the belt adjusting power source is in transmission connection with the belt adjusting screw rod 54, and the belt adjusting sliding seat 51 is in threaded connection with the belt adjusting screw rod 54. The belt adjusting power source drives the belt adjusting screw rod 54 to rotate, so that the belt adjusting sliding seat 51 can be driven to move accurately. Of course, the belt adjusting power source is a motor.

In order to fix the movable slide 47 after displacement, the utility model is characterized in that a fastening screw is connected to the movable slide 47 in a threaded manner, and the fastening screw can act on the adjusting slide 48. After the position of the moving slide 47 is adjusted, the fastening screw is tightened to act on the adjusting slide 48, so that the position of the moving slide 47 is fixed and no displacement occurs.

In order to enable the belts 45 to be maximally close to each other so as to meet the processing requirement of small-size paperboards, the utility model is provided with two groups of parallel adjusting slide rails 48, each group of adjusting slide rails 48 is provided with a movable wheel assembly, and each movable wheel assembly is hung with one belt. Because the two moving wheel assemblies on the two adjusting slide rails 48 can be placed back and forth, the two moving wheel assemblies are staggered in the left-right direction, and the two belts 45 on the two moving wheel assemblies can be very close, so that the two belts 45 cannot be close because the two moving wheel assemblies collide together in the left-right direction.

Of course, each set of adjustment slide 48 corresponds to one of the dials 53. Each of the dials 53 adjusts a set of moving wheel assemblies on the adjustment slide 48.

The driven wheel 46 of the present utility model is connected to an adjustment lever 460, and the adjustment lever 460 is mounted on the moving slide 47 so as to be adjustable back and forth (the adjustment is performed in a long hole of the adjustment lever 460 by a bolt). When the adjusting lever 460 is adjusted to move the front and rear positions of the slide 47, the front and rear positions of the driven wheel 46 can be adjusted, and the tension of the belt 45 can be adjusted.

Each set of adjustment slide rails 48 of the present utility model is comprised of two parallel optical axes. The two parallel optical axes can prevent the moving slide 47 from turning, and ensure that the moving slide 47 moves only in the lateral direction.

In order to adjust the position of the slotting cutter 43, a cutter guide rail 430 parallel to the roller shaft of the slotting roller 42 is arranged on the frame 1, a cutter slide seat 431 is arranged on the cutter guide rail 430 in a sliding way, and the slotting cutter 43 is arranged on the cutter slide seat 431; the machine frame 1 is provided with a cutter adjusting mechanism 6, the cutter adjusting mechanism 6 comprises a cutter adjusting guide rail 64, a cutter adjusting power source, a cutter adjusting seat 62, a bolt power source 61 and a bolt 60, the cutter adjusting seat 62 is arranged on the cutter adjusting guide rail 64 in a sliding mode, the cutter adjusting power source can drive the cutter adjusting seat 62 to move on the cutter adjusting guide rail 64, the bolt power source 61 is arranged on the cutter adjusting seat 62, and the bolt power source 61 can drive the bolt 60 to act on the cutter sliding seat 431.

The principle of adjustment of the slotting cutter 43 is as follows: as shown in fig. 5 and 6, when the position of the slotting cutter 433 needs to be adjusted, the pin power source 61 of the cutter adjusting mechanism 6 drives the pin 60 to act on the cutter slide 431, so that the pin 60 and the cutter slide 431 form a locking relationship, then the cutter adjusting power source drives the cutter adjusting seat 62 to move on the cutter adjusting guide rail 64 (specifically, the cutter adjusting power source drives the cutter adjusting screw 63 to drive the cutter adjusting seat 62 to move, the pin power source 61 of the cutter adjusting screw 63, which is installed on the cutter adjusting seat 62 at a precise adjusting position, moves on the cutter guide rail 430 through the pin 60 with the cutter slide 431, and the slotting cutter 43 thereby realizes position adjustment.

The latch 60 may be directly applied to the tool slide 431 in a locking relationship (face-to-face contact, friction to form a locking relationship), but the locking force may be insufficient, and in order to form a sufficiently strong locking force, the present utility model mounts the positioning groove 433 on the tool slide 431, and the latch 60 may be driven by the latch power source 61 to enter the positioning groove 433. With this structure, the latch 603 can be ensured to stably drive the cutter slider 431 to move. It should be noted that, the positioning slot 433 and the latch 60 may be interchanged, that is, the latch power source 61 drives the positioning slot 433 to move, and the latch 60 is connected to the cutter carriage 431. This also enables the attachment of the positioning slot 433 to the latch 60, although this is within the scope of the present utility model.

After the slotting cutter 43 is well adjusted, the slotting cutter 43 needs to be fixed, as shown in fig. 7 and 8, for this purpose, the slotting cutter 43 is installed on a cutter bar seat 434, the cutter bar seat 434 is slidably arranged on a cutter slide seat 431, a cutter power source 432 for driving the cutter bar seat 434 to slide is installed on the cutter slide seat 431, the cutter bar seat 434 can move back and forth by driving the cutter power source 432, in addition, a positioning column 49 capable of moving up and down is arranged on the cutter slide seat 431, and an action inclined plane 435 capable of acting on the positioning column 49 and making the positioning column 49 move down is arranged on the cutter bar seat 434. When the slotting cutter 43 is well positioned, the cutter power source 432 drives the cutter bar seat 434 to move, and the cutter bar seat 434 drives the positioning column 49 to move downwards through the action inclined plane 435, so that the positioning column 49 acts on the lower guide rail seat, and the cutter slide seat 431 is locked, and the slotting cutter 43 cannot move left and right.

In order to alleviate the hard contact between the positioning post 49 and the guide rail seat, as shown in fig. 8, the positioning post 49 includes a main post 490 and an operating post 491, the operating post 491 is vertically movably sleeved on the lower portion of the main post 490, and a spring 492 is provided between the main post 490 and the operating post 491. Since the operation post 491 is retractable by the spring 492, the operation post 491 acts on the rail seat with a certain buffer, thereby protecting the positioning post 49 and the rail seat.

In order to reduce friction between the main column 490 and the action inclined plane 435, the steel ball 493 is embedded at the upper end of the main column 490, and the steel ball 493 and the action inclined plane 435 act, so that the friction force is smaller, the abrasion is less and the noise is lower because the steel ball 493 and the action inclined plane 435 are in point contact.

In order to enable the deviation correcting backup plate 31 of the paperboard deviation correcting mechanism 3 to be adjustable, the paperboard deviation correcting mechanism 3 is arranged on a movable seat 35, and as shown in fig. 9, the movable seat 35 is slidably and adjustably arranged on a transverse guide rail 36; the deviation correcting backup plate 31 can be horizontally rotated and adjusted through the pin shaft 32.

The deviation rectifying and adjusting principle of the paperboard deviation rectifying mechanism 3 is as follows: if one of the batches of cardboard has beveled edges, the angle and position of the deviation correcting fence 31 will be adjusted as shown in fig. 12 and 13. Firstly, the deviation rectifying backup plate 31 is adjusted to horizontally rotate around the pin shaft 32, so that the front edge of the paper board B is parallel to the roller datum line D of the grooving roller 42 after the paper board B leans against the deviation rectifying backup plate 31 (namely is flush with the backup plate datum line K of the deviation rectifying backup plate 31); and then the movable seat 35 is driven to move on the transverse guide rail 36, so that the deviation rectifying backup plate 31 moves left and right, after the left and right positions of the deviation rectifying backup plate 31 are determined, the paper board B leans against the deviation rectifying backup plate 31 again under the action of the deviation rectifying wheels, so that the groove line X of the required groove of the paper board B is aligned with the groove cutting tool 43 when the paper board enters the paper board grooving mechanism 4, and the paper board B can enter the paper board grooving mechanism 4 at the position shown in fig. 13. Because the front edge of the paper board B is parallel to the roller datum line D of the grooving roller 42, when the paper board B enters between the grooving roller 42 and the belt 45, the grooving roller 42 and the belt 45 can just press the front edge of the paper board B, so that the paper board B moves along with the rotation of the grooving roller 42, the paper board B cannot rotate, and the position of the grooved line X of the paper board is more stable.

In order to drive the deviation correcting backup plate 31 to horizontally rotate around the pin shaft 32, as shown in fig. 10, a guide rail seat 333 is installed on the moving seat 35, a linear guide rail 334 extending transversely is installed on the guide rail seat 333, an adjusting slide block 335 is slidably arranged on the linear guide rail 334, the adjusting slide block 335 is connected with a rotating adjusting nut 336, the rotating adjusting nut 336 is connected with the deviation correcting backup plate 31 through a connecting piece 337, and the rotating adjusting nut 336 is in threaded connection with a rotating adjusting screw 338. Through rotating the rotary adjusting screw 338, the rotary adjusting screw 338 drives the rotary adjusting nut 336 to move on the linear guide rail 334, and the rotary adjusting nut 336 drives the deviation rectifying backup plate 331 to move through the connecting piece 337, so that the deviation rectifying backup plate 31 can horizontally rotate around the pin shaft 32, and angle adjustment is achieved.

Since the deviation rectifying backup plate 31 horizontally rotates around the pin shaft 32, any point on the deviation rectifying backup plate 31 moves along the arc track, and can be adjusted by the adjusting mode under the condition of small adjusting angle, if the adjusting angle is large, the arc track problem of the deviation rectifying backup plate 31 also needs to be considered. For this purpose, as shown in fig. 10, the lower guide rail 330 extending longitudinally is connected to the deviation correcting backup plate 31, and a lower slide 331 is slidably provided on the lower guide rail 330, and the lower slide 331 is connected to the connecting member 337. Through this structure, when the deviation rectifying backup plate 31 rotates in a large angle, the lower guide rail 330 on the deviation rectifying backup plate 31 moves relative to the lower slide seat 331, that is, the rotating adjusting nut 36 is flexibly connected with the deviation rectifying backup plate 31, so as to prevent the deviation rectifying backup plate 31 from being blocked.

In order to facilitate the adjustment of the rotation of the deviation rectifying backup plate 31, the rotary adjusting screw 338 is in transmission connection with the rotary adjusting power source 33, the rotary adjusting power source 33 is a servo motor, and the rotary adjusting screw 338 realizes the rotation through the driving of the rotary adjusting power source 33, so that the deviation rectifying backup plate 31 realizes the rotation. Of course, the rotary adjustment screw 338 may also be rotated manually. Both of which fall within the scope of the present utility model.

Also for the convenience of adjusting the deviation correcting backup plate 31 to move left and right, the movable seat 35 is in transmission connection with a transverse adjusting power source 39 driving the movable seat 35 to move on a transverse guide rail 36. The movable seat 35 is moved left and right by driving the lateral adjustment power source 39. Of course, the movement of the movement seat 35 can also be achieved manually. Both of which fall within the scope of the present utility model.

In order to drive the movable seat 35 to move, the movable seat 35 is connected with a transverse adjusting nut, the transverse adjusting nut is in threaded connection with a transverse adjusting screw rod 37, a transverse adjusting power source 39 is in drive connection with the transverse adjusting screw rod 37, and the transverse adjusting power source 39 is a servo motor. The transverse adjusting screw rod 37 rotates by driving the transverse adjusting power source 39 to drive the transverse adjusting nut to move together with the moving seat 35.

By adopting a power source driving adjustment mode, only the parameters to be adjusted are required to be input into a power source controller, the power source controller is used for controlling the rotation adjustment power source 33 to output and adjust the angle of the deviation correction backup plate 31, the transverse adjustment power source 39 is used for outputting and adjusting the position of the deviation correction backup plate 31, and finally, the paperboard enters the paperboard slotting mechanism 4 after correcting the position, so that a common worker can also adjust the paperboard more easily.

In order to facilitate the alignment of the sheet in the right-left direction with the slotting cutter 43, the sheet feeding conveyor mechanism 2 of the present utility model is also mounted on the movable seat 35 as shown in fig. 11. When the movable base 35 moves, the paper feed conveyance mechanism 2 moves left and right together with the deviation correcting backup plate 31. After the deviation rectifying backup plate 31 rotates to adjust the angle, the deviation rectifying backup plate 31 and the movable seat 35 integrally move left and right, so that the correction is more convenient.

Claims (12)

1. A full-automatic adjustable paperboard grooving machine comprises a frame (1), a paper feeding conveying mechanism (2), a paperboard deviation correcting mechanism (3) and a paperboard grooving mechanism (4); the paperboard deviation correcting mechanism (3) comprises a deviation correcting backup plate (31); cardboard slotting mechanism (4) are including fluting cutter (43), grooving roller (42), belt (45) and belt roller (44), its characterized in that: a cutter guide rail (430) parallel to the roller shaft of the grooving roller (42) is arranged on the frame (1), a cutter sliding seat (431) is arranged on the cutter guide rail (430) in a sliding mode, and the grooving cutter (43) is arranged on the cutter sliding seat (431); the machine frame (1) is provided with a cutter adjusting mechanism (6), the cutter adjusting mechanism (6) comprises a cutter adjusting power source, a cutter adjusting guide rail (64), a cutter adjusting seat (62), a bolt power source (61) and a bolt (60), the cutter adjusting seat (62) is arranged on the cutter adjusting guide rail (64) in a sliding mode, the bolt power source (61) can drive the cutter adjusting seat (62) to move on the cutter adjusting guide rail (64), the bolt power source (61) is arranged on the cutter adjusting seat (62), and the bolt power source (61) can drive the bolt (60) to act on the cutter sliding seat (431); an adjusting slide rail (48) is arranged on the frame (1), a moving wheel assembly is arranged on the adjusting slide rail (48), the moving wheel assembly comprises a driven wheel (46) and a moving slide seat (47), the belt (45) is wound on the driven wheel (46), the driven wheel (46) is connected to the moving slide seat (47), and the moving slide seat (47) is slidably arranged on the adjusting slide rail (48); install belt adjustment mechanism (5) on frame (1), belt adjustment mechanism (5) are including transferring area guide rail (50), transferring area slide (51), transferring area power supply, shifting block (53) and shifting block power supply (52), shifting block power supply (52) are installed on transferring area slide (51), transferring area slide (51) slip is established on transferring area guide rail (50), transferring area power supply can drive transferring area slide (51) and remove on transferring area guide rail (50), shifting block power supply (52) can drive shifting block (53) and act on removal slide (47).

2. A fully automatic adjustable paperboard grooving machine according to claim 1, characterized in that: the paperboard deviation correcting mechanism (3) is arranged on the movable seat (35), and the movable seat (35) is slidably and adjustably arranged on the transverse guide rail (36); the deviation correcting backup plate (31) can be horizontally rotated and adjusted through a pin roll (32).

3. A fully automatic adjustable paperboard grooving machine according to claim 2, characterized in that: install guide rail seat (333) on moving seat (35), install transversely extending's linear guide (334) on guide rail seat (333), the last slip of linear guide (334) is equipped with regulation slider (335), regulation slider (335) are connected with rotatory adjusting nut (336), rotatory adjusting nut (336) threaded connection is on rotatory adjusting screw (338), be connected with vertically extending's lower guide rail (330) on rectifying backup plate (31), slide down slide (331) are equipped with on lower guide rail (330), lower slide (331) are connected with rotatory adjusting nut (336).

4. A fully automatic adjustable paperboard grooving machine according to claim 3, characterized in that: the rotary adjusting screw rod (338) is in transmission connection with a rotary adjusting power source (339); the movable seat (35) is in transmission connection with a transverse adjusting power source (39) which drives the movable seat (35) to move on a transverse guide rail (36).

5. The fully automatic adjustable paperboard grooving machine according to claim 4, characterized in that: the movable seat (35) is connected with a transverse adjusting nut, the transverse adjusting nut is connected to a transverse adjusting screw rod (37) in a threaded mode, and the transverse adjusting power source (39) is connected with the transverse adjusting screw rod (37) in a transmission mode.

6. A fully automatic adjustable paperboard grooving machine according to claim 2, characterized in that: the paper feeding and conveying mechanism (2) is arranged on the movable seat (35), and the paper feeding and conveying mechanism (2) comprises a conveying belt or a conveying roller.

7. A fully automatic adjustable paperboard grooving machine according to claim 1, characterized in that: the grooving cutter (43) is arranged on a cutter bar seat (434), the cutter bar seat (434) is arranged on a cutter slide seat (431) in a sliding mode, a cutter power source (432) for driving the cutter bar seat (434) to slide is arranged on the cutter slide seat (431), a positioning column (49) capable of moving up and down is arranged on the cutter slide seat (431), and an action inclined plane (435) capable of acting on the positioning column (49) and enabling the positioning column (49) to move downwards is arranged on the cutter bar seat (434).

8. The fully automatic adjustable paperboard grooving machine according to claim 7, characterized in that: the positioning column (49) comprises a main column (490) and an action column (491), wherein the action column (491) is sleeved at the lower part of the main column (490) in a vertically movable mode, and a spring (492) is arranged between the main column (490) and the action column (491).

9. A fully automatic adjustable paperboard grooving machine according to claim 1, characterized in that: the movable slide (47) is connected with a fastening screw in a threaded manner, and the fastening screw can act on the adjusting slide rail (48).

10. A fully automatic adjustable paperboard grooving machine according to claim 1, characterized in that: the belt adjusting power source is in transmission connection with the belt adjusting screw rod (54), and the belt adjusting sliding seat (51) is in threaded connection with the belt adjusting screw rod (54).

11. A fully automatic adjustable paperboard grooving machine according to claim 1, characterized in that: the adjusting slide rails (48) are provided with two groups and are parallel, each group of adjusting slide rails (48) is provided with a moving wheel assembly, and each group of adjusting slide rails corresponds to one shifting block (53).

12. A fully automatic adjustable paperboard grooving machine according to claim 1, characterized in that: the movable slide seat (47) is provided with a positioning pin hole (470), and the shifting block power source (52) can drive the shifting block (53) to be inserted into the positioning pin hole (470) of the movable slide seat (47).