CN112847544A - Full-automatic transverse-vertical cutting machine - Google Patents

Abstract

The invention discloses a fully automatic horizontal and vertical cutting machine, comprising a first worktable, a cutter device, a driving device, a first propulsion device, a second worktable, a second propulsion device and a position adjustment device; the first propulsion device The device is movably arranged on the first table; the cutter device is arranged between the first table and the second table and can slide along the width direction of the first table; The driving device drives the cutter device to slide to cut the material; the second propulsion device is movably arranged on the second workbench; the second workbench is set at the output end of the position adjustment device, The position adjusting device can drive the second worktable to rotate. The fully automatic horizontal and vertical cutting machine of the invention can automatically cut the material horizontally and vertically without manual operation and has high production efficiency.

Description

Full-automatic transverse-vertical cutting machine

Technical Field

The invention relates to a full-automatic transverse and vertical cutting machine, in particular to a full-automatic transverse and vertical cutting machine which can automatically cut materials transversely and longitudinally, does not need manual operation and has high production efficiency.

Background

The existing cutting of the pearl wool is mainly performed by a cutting machine, for example, a pearl wool sheet is cut into a plurality of small pearl wool squares by a semi-automatic vertical cutting machine. The frame of the vertical cutting machine is fixed, the workbench moves, and the pearl cotton sheet is cut into a plurality of pearl cotton slivers; then, the pearl cotton sliver is manually adjusted to be rotated by 90 degrees, and then is cut into a plurality of pearl cotton squares. The production form of one-way cutting and manual steering has low automation degree and low production efficiency.

Disclosure of Invention

The invention aims to provide a full-automatic transverse and vertical cutting machine which can automatically cut materials transversely and longitudinally, does not need manual operation and has high production efficiency.

In order to achieve the purpose, the full-automatic transverse and vertical cutting machine provided by the invention comprises a first workbench, a cutter device, a driving device, a first propelling device, a second workbench, a second propelling device and a position adjusting device; the first propelling device is movably arranged on the first workbench; the cutter device is arranged between the first workbench and the second workbench and can slide along the width direction of the first workbench; the driving device drives the cutter device to slide so as to cut the material; the second propelling device is movably arranged on the second workbench; the second workbench is arranged at the output end of the position adjusting device, and the position adjusting device can drive the second workbench to rotate.

Compared with the prior art, the cutting device is arranged in a sliding manner along the width direction of the first workbench, the driving device is used for driving the cutting device to slide, and the first propelling device is used for pushing the material to feed, so that the cutting device can cut the material loaded on the first workbench. And the position adjusting device is arranged below the second workbench and used for adjusting the positions of the second workbench and the material, so that the material can rotate by 90 degrees, the material can be pushed by the second pushing device and can be cut by the cutter device, and the material can be formed into a plurality of small squares. The whole process is automatically completed through the matching of each device, manual operation is not needed, the production efficiency is effectively improved, meanwhile, accidents caused by manual operation are avoided, and the production safety is improved.

Preferably, the position adjusting device includes a bracket, a translation device, a sliding table and a rotating device, the second working table is disposed at an output end of the rotating device, the rotating device is disposed at the sliding table, the sliding table is connected to an output end of the translation device, and the translation device is disposed on the bracket. Through setting up rotating device can make second workstation and material can rotate certain angle to reach the purpose of adjustment material position, and make the material can be followed another angle once more by the cutters cuts, and then reach the purpose of cutting into the square. In addition, through setting up the translation device can make material and second workstation horizontal migration leave before rotating first workstation to prevent that second workstation from taking place to disturb with first workstation, guarantee material turned angle's accuracy.

Specifically, the translation device comprises a translation motor, a screw rod and a sliding block, the screw rod is pivoted to the bracket, and the sliding block is in threaded connection with the screw rod and is connected with the sliding table. The accuracy of the translation position can be improved by utilizing the screw rod and the sliding block to drive the sliding table to slide.

Specifically, rotating device is including rotating motor, drive pulley, driven pulley, belt and axis of rotation, the axis of rotation pin joint in on the sliding stand, driven pulley is fixed in the axis of rotation, drive pulley is fixed in the output of rotating the motor, the belt twine in on drive pulley and the driven pulley, rotate the motor set up in on the sliding stand.

Specifically, the rotating device further comprises a tray and a bearing, wherein the bearing is arranged between the tray and the sliding table, and the tray is concentrically connected with the rotating shaft.

Specifically, a guide slide rail is arranged between the sliding table and the bracket.

Preferably, the first propelling device and/or the second propelling device comprises a clamping plate and a driving mechanism for driving the clamping plate, and the driving mechanism drives the clamping plate to further drive the materials to move.

Preferably, the cutter device comprises a frame body, a driving motor, a cutter belt and a plurality of driving wheels, the driving wheels are pivoted on the frame body, the cutter belt is wound on the driving wheels, and the driving motor drives the driving wheels to rotate so as to drive the cutter belt to operate.

Drawings

FIG. 1 is a perspective view of the fully automatic transverse and vertical cutting machine of the present invention.

FIG. 2 is a front view of the fully automatic transverse and vertical cutting machine of the present invention.

FIG. 3 is a top view of the fully automatic transverse and vertical cutting machine of the present invention.

FIG. 4 is a side view of the fully automatic transverse and vertical cutting machine of the present invention.

FIG. 5 is a perspective view of the position adjusting device of the fully automatic horizontal and vertical cutting machine of the present invention.

FIG. 6 is an exploded view of the position adjustment device of the fully automatic transverse-vertical cutting machine of the present invention.

FIG. 7 is a side view of a second table of the fully automatic cross-vertical cutting machine of the present invention.

Fig. 8 is a side view of the cutter assembly of the fully automatic transverse and vertical cutting machine of the present invention.

FIG. 9 is a diagram of the fully automatic horizontal-vertical cutting machine of the present invention after the second worktable rotates 90 degrees.

Detailed Description

In order to explain technical contents, structural features, and effects achieved by the present invention in detail, the following detailed description is given with reference to the embodiments and the accompanying drawings.

As shown in fig. 1 to 4, the fully automatic transverse and vertical cutting machine 100 of the present invention comprises a first worktable 1, a second worktable 2, a cutter device 3, a driving device 4, a first propelling device 5, a second propelling device 6 and a position adjusting device 7; the first propelling device 5 is movably arranged on the first workbench 1 and can push the materials to move towards the second workbench 2. The cutter device 3 is arranged between the first workbench 1 and the second workbench 2 and can slide along the width direction of the first workbench 1; the driving device 4 drives the cutter device 3 to slide so as to cut the material; the second propelling device 6 is movably arranged on the second workbench 2 and can push the materials to move towards the first workbench 1; the second workbench 2 is arranged at the output end of the position adjusting device 7, and the position adjusting device 7 can drive the second workbench 2 to rotate.

Referring to fig. 2, 4 to 6, the position adjusting device 7 includes a bracket 71, a translation device 72, a sliding table 73 and a rotation device 74, the second worktable 2 is disposed at an output end of the rotation device 74, the rotation device 74 is disposed at an upper side of the sliding table 73, the sliding table 73 is connected to the output end of the translation device 72, and a guide rail 75 is disposed between the sliding table 73 and the bracket 71 so that the sliding table 73 can be supported on the bracket 71 and can slide relative to the bracket 71. The translation device 72 is located below the sliding table 73 and disposed on the bracket 71, and can drive the sliding table 73 to translate. The second workbench 2 and the materials can rotate by a certain angle by arranging the rotating device 74, so that the purpose of adjusting the position of the materials is achieved, the materials can be cut by the cutter device 3 from another angle again, and the purpose of cutting the materials into squares is achieved. In addition, through setting up translation device 72, can make material and second workstation 2 horizontal migration leave before the rotation first workstation 1 to prevent that second workstation 2 from interfering with first workstation 1, guarantee material turned angle's accuracy. Specifically, the translation device 72 includes a translation motor 721, a lead screw 722 and a slider 723, the lead screw 722 is pivotally connected to the bracket 71, and the slider 723 is threadedly connected to the lead screw 722 and connected to the sliding table 73. The accuracy of the translation position can be improved by driving the sliding table 73 to slide by the lead screw 722 and the sliding block 723. The rotating device 74 includes a rotating motor 741, a driving pulley 742, a driven pulley 743, a belt 744 and a rotating shaft 745, the rotating shaft 745 is pivotally connected to the sliding table 73, the driven pulley 743 is fixed to the rotating shaft 745, the driving pulley 742 is fixed to an output end of the rotating motor 741, the belt 744 is wound around the driving pulley 742 and the driven pulley 743, and the rotating motor 741 is disposed on the sliding table 73. The rotating device 74 further includes a tray 746 and a bearing 747, the bearing 747 is disposed between the tray 746 and the sliding table 73, and the tray 746 is concentrically coupled to the rotating shaft 745.

As shown in fig. 2 and 7, the first pushing device 5 includes a first clamp plate 51 and a first driving mechanism 52 for driving the first clamp plate 51, wherein rails are provided on both side edges of the first table 1, and the first clamp plate 51 is slidably provided on the rails. The first driving mechanism 52 drives the first clamping plate 51 to drive the material to move. The second pushing device 6 also comprises a second clamping plate 61 and a second driving mechanism 62 for driving the second clamping plate 61, two side edges of the second workbench 2 are also provided with tracks, and the second clamping plate 61 is slidably arranged on the tracks. The second driving mechanism 62 drives the second clamping plate 61 to drive the material to move.

Referring to fig. 1, 2 and 8, the cutter device 3 includes a frame 31, a driving motor 32, a blade 33 and a plurality of driving wheels 34, the driving wheels 34 are pivotally connected to the frame 31, the blade 33 is wound around the driving wheels 34, and the driving motor 32 drives the driving wheels 34 to rotate to drive the blade 33 to operate. A gap 100a is formed between the first table 1 and the second table 2, and the blade tape 33 of the cutter device 3 passes through the gap 100 a.

In addition, the first driving mechanism 52, the second driving mechanism 62 and the driving device 4 are driven by driving a belt through a motor, and then the belt is connected with a corresponding moving part to drive the moving part to move, which is not described in detail herein.

In combination with the above description and with reference to fig. 1 and 9, the following describes the working principle of the fully automatic transverse and vertical cutting machine 100 of the present invention in detail, as follows:

first, the first driving mechanism 52 is controlled to move the first clamp plate 51 to the front end portion of the first table 1, and the second driving mechanism 62 is controlled to move the second clamp plate 61 to the side of the second table 2. At this time, the pearl wool sheet is placed on the first table 1. Then, the first driving mechanism 52 drives the first clamping plate 51 to move, and further drives the pearl cotton sheet to move by a step distance in the direction of the second workbench 2, wherein the step distance is equal to the length of the square to be cut. Then, the cutter device 3 is started, the driving motor 32 drives the knife belt 33 to operate, and the knife belt 33 starts to cut the pearl cotton sheet; meanwhile, the driving device 4 drives the cutter device 3 to move along the width direction of the first workbench 1, so that the cutter belt 33 cuts a strip-shaped pearl cotton material on the pearl cotton sheet. When the cutting is finished, the first driving mechanism 52 drives the pearl cotton sheet to move one step towards the second workbench 2. Then, the cutter device 3 continues to cut a second strip of pearl cotton material along the direction opposite to the previous time. And cutting the pearl cotton sheet into a plurality of strips. At this time, the first pushing device 5 brings the strip-shaped pearl wool sheets to the rear section of the second table 2. At this time, the translation motor 721 of the translation device 72 of the position adjusting device 7 is started to drive the screw rod 722 to rotate, and the screw rod 722 drives the rotation device and the second worktable 2 to be away from the first worktable 1 through the slider 723. Then, the rotating device 74 is activated, the rotating motor 741 drives the driving pulley 742, and the driving pulley 742 drives the driven pulley 743 and the belt 744 to rotate, so that the rotating shaft 745 and the tray 746 rotate, thereby rotating the second table 2. This application rotates 90 degrees through the output of control rotation motor 741, and then makes the cotton sheet of pearl of second workstation 2 and bar rotate 90 degrees. Finally, the translation means 72 drive the second work-table 2 to move again close to the first work-table 1. Then, under the cooperation of the second driving mechanism 62, the second clamping plate 61, the driving device 4 and the cutter device 3, the strip-shaped pearl cotton sheet moves towards the first workbench 1, so that the strip-shaped pearl cotton sheet is continuously cut, and the cutting opening is perpendicular to the cutting opening cut before rotation, so that the strip-shaped pearl cotton sheet forms a plurality of small square block-shaped materials.

Compared with the prior art, the cutting device 3 is arranged in a sliding manner along the width direction of the first workbench 1, the driving device 4 is used for driving the cutting device 3 to slide, and the first propelling device 5 is used for pushing the material to feed, so that the cutting device 3 can cut the material loaded on the first workbench 1. And the position adjusting device 7 is arranged below the second workbench 2, and the position of the second workbench 2 and the material is adjusted by the position adjusting device 7, so that the material can be rotated by 90 degrees, the material can be pushed by the second pushing device 6, the material is cut by the cutter device 3, and the material forms a plurality of small squares. The whole process is automatically completed through the matching of each device, manual operation is not needed, the production efficiency is effectively improved, meanwhile, accidents caused by manual operation are avoided, and the production safety is improved.

The above disclosure is only a preferred embodiment of the present invention, and certainly should not be taken as limiting the scope of the present invention, which is therefore intended to cover all equivalent changes and modifications within the scope of the present invention.

Claims (8)

1. A fully automatic horizontal and vertical cutting machine is characterized in that: comprising a first workbench, a cutter device, a driving device, a first propulsion device, a second workbench, a second propulsion device and a position adjustment device; the described The first propulsion device is movably disposed on the first workbench; the cutter device is disposed between the first workbench and the second workbench and can be along the width direction of the first workbench sliding; the driving device drives the cutter device to slide to cut the material; the second propulsion device is movably arranged on the second worktable; the second worktable is arranged on the position adjustment device At the output end, the position adjustment device can drive the second worktable to rotate. 2 . The fully automatic horizontal and vertical cutting machine according to claim 1 , wherein the position adjustment device comprises a bracket, a translation device, a sliding table and a rotating device, and the second worktable is arranged on the rotating device. 3 . The output end of the device, the rotating device is arranged on the sliding table, the sliding table is connected to the output end of the translation device, and the translation device is arranged on the bracket. 3. The fully automatic horizontal and vertical cutting machine according to claim 2, wherein the translation device comprises a translation motor, a screw rod and a slider, the screw rod is pivotally connected to the bracket, and the slider A block is threadedly connected to the lead screw and is connected to the rotating device. 4. The fully automatic horizontal and vertical cutting machine according to claim 2, wherein the rotating device comprises a rotating motor, a driving pulley, a driven pulley, a belt and a rotating shaft, and the rotating shaft is pivotally connected to the rotating shaft. On the sliding table, the driven pulley is fixed on the rotating shaft, the driving pulley is fixed on the output end of the rotating motor, the belt is wound on the driving pulley and the driven pulley, and the rotating motor is set on the sliding table. 5. The fully automatic horizontal and vertical cutting machine according to claim 4, wherein the rotating device further comprises a tray and a bearing, the bearing is arranged between the tray and the sliding table, and the tray Connected concentrically with the rotating shaft. 6 . The fully automatic horizontal and vertical cutting machine according to claim 2 , wherein a guide rail is provided between the sliding table and the bracket. 7 . 7 . The fully automatic horizontal and vertical cutting machine according to claim 1 , wherein the first propelling device and/or the second propelling device comprises a clamping plate and a driving mechanism for driving the clamping plate, and the driving mechanism drives the clamping plate. 8 . The splint then drives the material to move. 8 . The fully automatic horizontal and vertical cutting machine according to claim 1 , wherein the cutter device comprises a frame body, a driving motor, a blade belt and a plurality of driving wheels, and the driving wheels are pivotally connected to the The frame body, the knife belt is wound around the driving wheel, and the driving motor drives the driving wheel to rotate to drive the knife belt to run.

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