CN215881773U - Full-automatic guillootine - Google Patents

Abstract

The utility model discloses a full-automatic cutting machine which comprises a main frame, a main upright post, an X-direction fixed beam, an X-direction driving assembly, a Y-direction movable beam, a Y-direction driving assembly, a Z-direction lifting beam, a Z-direction driving assembly, a rotary moving support seat, a cutting tool and a material pressing mechanism, wherein one end of the Y-direction movable beam is assembled on the main upright post through a slewing bearing, the other end of the Y-direction movable beam is provided with a first transition plate, the rotary moving support seat is assembled on the X-direction fixed beam, the bottom surface of the first transition plate can be rotatably assembled on the rotary moving support seat, the end surface of the first transition plate is assembled on the Y-direction movable beam, the Z-direction lifting beam can be assembled on the Y-direction movable beam through a second transition plate in a lifting manner, the cutting tool is assembled on the Z-direction lifting beam, and the material pressing mechanism is configured to press and fix a plate during cutting. The full-automatic cutting machine is ingenious in design, high in automation degree and capable of improving production efficiency; and the processing precision is high, and the processingquality is good, has reduced the processing cost, and safe reliability is high.

Description

Full-automatic guillootine

Technical Field

The utility model belongs to the technical field of plate cutting equipment, and particularly relates to a full-automatic cutting machine suitable for cutting plates.

Background

The guillootine is the main equipment that is used for panel processing, has had the panel guillootine of multiple form in the existing market, but generally exists following shortcoming in specific application process:

1) the cutting quality is unstable, and the precision is not high;

2) the speed is slow, and the productivity is low;

3) high cost and unsafe production.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a full-automatic cutting machine, which solves the problems of low cutting efficiency and poor precision of the cutting machine in the prior art.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a full-automatic guillootine, it includes main frame, head tree, X to fixed beam, X to drive assembly, Y to walking beam, Y to drive assembly, Z to lifting beam, Z to drive assembly, rotary motion supporting seat, cuts cutter and swager construct, wherein, be provided with on the terminal surface of main frame and cut the platform, cut and vertically be fixed with the head tree on the main frame of platform one side, be fixed with on the main frame of opposite side along X that X axle direction extends to the fixed beam, Y to the one end of walking beam pass through swivel bearing assemble in the top of head tree, the first cab apron of crossing is installed to the other end, the rotary motion supporting seat assemble in X is to on the fixed beam, X drives to drive assembly the rotary motion supporting seat along X to reciprocating motion, the first bottom surface of crossing the cab apron can assemble with rotating on the rotary motion supporting seat, the terminal surface can be followed Y axle direction and assembled with moving in Y is to the walking beam, Z to the lifing beam pass through the second cab apron can assemble with going up and down in Y is to the walking beam, Y drives to drive assembly Z is to the lifing beam along Y to reciprocating motion, cut the cutter assembly in Z is to on the lifing beam, Z drives to drive assembly Z is to the lifing beam along Z to reciprocating motion, it is connected with cutter drive arrangement to cut the cutter, swager constructs to compress tightly fixedly to panel on the cutting platform when being configured to cut.

Further say, the feeding side that cuts the platform is provided with automatic feeding line, automatic feeding line includes pay-off wire frame, driving belt, initiative conveying roller, driven conveying roller, servo motor and side locating plate, initiative conveying roller and driven conveying roller assemble respectively in the both ends of pay-off wire frame, servo motor pass through synchronous belt drive assembly with initiative conveying roller transmission is connected, the driving belt cover is on initiative conveying roller and driven conveying roller.

Furthermore, a plurality of supporting legs are installed at the bottom of the feeding wire frame, wherein the supporting legs on at least one side are of detachable structures and are fixed on the feeding wire frame through bolts so that the transmission belt can be conveniently sleeved on the feeding wire frame in a smaller circumference.

Furthermore, a bakelite plate is arranged on the cutting platform, and a plurality of through holes are formed in the bakelite plate and communicated with a dust collection cover below the table top.

The material pressing mechanism comprises a front material pressing frame and a rear material pressing frame which are arranged on the Y-direction movable beam, material pressing cylinders are arranged on the front material pressing frame and the rear material pressing frame, and the driving ends of the material pressing cylinders are connected with a material pressing plate.

Further say, X is to drive assembly including two X to linear guide, X to drive rack and X to servo motor, two X to linear guide and X to drive rack parallel interval and along X to be fixed in to extending on the fixed beam X, the bottom of rotary movable supporting seat is passed through the slider and is assembled on two X to linear guide, X is fixed in to servo motor on the rotary movable supporting seat, just X is to servo motor's drive end install with X to the drive gear that drives rack and mesh.

Furthermore, the Y-direction driving assembly comprises two Y-direction linear guide rails, a Y-direction driving rack and a Y-direction servo motor, the two Y-direction linear guide rails and the Y-direction driving rack are parallelly spaced and are fixed on the Y-direction movable beam in a manner of extending along the Y direction, the second transition plate is assembled on the two Y-direction linear guide rails through a sliding block, the Y-direction servo motor is fixed on the second transition plate, and a driving gear meshed with the Y-direction driving rack is installed at the driving end of the Y-direction servo motor.

Furthermore, the Z-direction driving assembly comprises two Z-direction linear guide rails, a ball screw, a screw nut and a Z-direction servo motor, the two Z-direction linear guide rails and the ball screw are arranged in parallel at intervals and are assembled on the Z-direction lifting beam in a manner of extending along the Z direction, the second transition plate is assembled on the two Z-direction linear guide rails and the ball screw through a sliding block and the screw nut respectively, the Z-direction servo motor is installed at the top of the Z-direction lifting beam, and the driving end of the Z-direction servo motor is connected with the ball screw.

Furthermore, the bottom surface of the first transition plate is assembled on the top of the rotary moving support seat through a rotary bearing, and the end surface of the first transition plate is assembled on two short linear guide rails fixed at the end part of the Y-direction movable beam through a sliding block.

Compared with the prior art, the full-automatic cutting machine has the advantages that the design is ingenious, the automation degree is high, and the production efficiency is improved; and the processing precision is high, and the processingquality is good, has reduced the processing cost, and safe reliability is high.

Drawings

Fig. 1 is a schematic perspective view of a fully automatic cutting machine according to an embodiment of the present invention;

fig. 2 is a schematic perspective view of a main body portion of a fully automatic cutting machine according to an embodiment of the present invention;

fig. 3 is a schematic perspective view of an automatic feeding line of a fully automatic cutting machine according to an embodiment of the present invention.

Detailed Description

The technical scheme of the utility model is further explained by the specific implementation mode in combination with the attached drawings.

To facilitate an understanding of the utility model, the utility model will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete. It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 to 3, in the present embodiment, a full-automatic cutting machine includes an automatic feeding line 1 and a main machine portion, the automatic feeding line 1 is disposed on a feeding side of the main machine portion, and includes a feeding wire frame 2, a driving belt 3, a driving transmission roller 4, a driven transmission roller 5, a feeding servo motor 6 and a side positioning plate, a plurality of support legs 29 are installed at a bottom of the feeding wire frame 2, wherein the support legs 29 on one side are detachably fixed to the feeding wire frame 2 by bolts, so that the driving belt 3 can be sleeved on the feeding wire frame 2 with a smaller circumference. Initiative conveying cylinder 4 assembles in the one end of pay-off wire frame 2 through the rolling bearing, driven conveying cylinder 5 assembles in the other end of pay-off wire frame 2 through adjustable balladeur train bearing frame, the primary function of adjustable balladeur train bearing frame is just to carry out the tensioning to driving belt, pay-off servo motor 6 passes through synchronous belt drive subassembly and is connected with initiative conveying cylinder 4 transmission, driving belt 3 covers on initiative conveying cylinder 4 and driven conveying cylinder 5, the side locating plate is installed in one side of driving belt 3 and is extended along the pay-off direction.

The main machine part comprises a main machine frame 7, a main upright post 8, an X-direction fixed beam 9, a Y-direction movable beam 10, a Z-direction lifting beam 11, a rotary moving support seat 12 and a cutting tool 13, wherein a cutting platform is arranged on the end surface of the main machine frame 7, a layer of bakelite plate 14 is arranged on the cutting platform, a plurality of through holes are formed in the bakelite plate 14 and communicated with a dust collecting cover 28 below a table top, the main upright post 8 is vertically fixed on one side of the cutting platform on the main machine frame 7, an X-direction fixed beam 9 extending in the X-axis direction is fixed on the other side opposite to the side where the main upright post 8 is arranged, two X-direction linear guide rails 15 and an X-direction driving rack 16 extending in the X-direction are fixed on the X-direction fixed beam 9, the bottom of the rotary moving support seat 12 is assembled on the two X-direction linear guide rails 15 through a slide block, an X-direction servo motor 17 is fixed on the rotary moving support seat 12, a driving gear meshed with the X-direction driving gear 16 is installed at the driving end of the X-direction servo motor 17, the X-direction servo motor 17 drives the rotary moving support seat 12 to reciprocate along the X direction through gear and rack transmission.

One end of the Y-direction movable beam 10 is fitted to the top of the main column 8 through a slewing bearing, and this end serves as a fixed rotation fulcrum. The other end is provided with a first transition plate 18, the bottom surface of the first transition plate 18 is assembled on the top of the rotary moving supporting seat 12 through a slewing bearing, and the end surface is assembled on two short linear guide rails fixed on the end part of the Y-direction movable beam 10 through a sliding block, so that the end can be used as a movable rotary fulcrum. Two Y-direction linear guide rails 19 and a Y-direction driving rack 20 which extend along the Y direction are arranged on the side surface of the Y-direction movable beam 10, two Z-direction linear guide rails and a ball screw which extend along the Z direction are arranged on the Z-direction lifting beam 11, one surface of a second transition plate 21 is connected on the two Y-direction linear guide rails 19 through a sliding block, the other surface of the second transition plate is respectively connected on the two Z-direction linear guide rails and the ball screw through a sliding block and a screw nut, a Y-direction servo motor 22 is fixed on the second transition plate 21, a driving gear which is meshed with the Y-direction driving rack 20 is arranged at the driving end of the Y-direction servo motor 22, the Y-direction servo motor 22 drives the Z-direction lifting beam 11 to reciprocate along the Y direction through gear-rack transmission, a Z-direction servo motor 23 is arranged at the top of the Z-direction lifting beam 11, the driving end of the Z-direction servo motor is connected with the ball screw, and a cutting tool 13 is fixedly assembled at the bottom of the Z-direction lifting beam 11, a cutting motor for driving the cutting tool 13 to rotate is mounted on the Z-direction lifting beam 11, and the Z-direction servo motor 23 drives the Z-direction lifting beam 11 to lift.

The blade is perhaps made panel production removal aversion along the power that produces when cutting panel of cutting path walking, in order to prevent panel aversion, Y is to installing preceding pressure work or material rest 24 and back pressure work or material rest 25 on the walking beam 10, all is provided with on the preceding pressure work or material rest 24 and the back pressure work or material rest 25 and presses material cylinder 26, presses the drive end of material cylinder 26 to connect and presses flitch 27, and the cylinder drives pressure flitch 27 and compresses tightly panel when cutting, and the cylinder loosens when not cutting. When the plate is cut, the pressing plates 27 positioned at two sides of the cutting path compress and fix the plate.

The Z-direction lifting beam 11 of the full-automatic cutting machine can reciprocate along X, Y and Z axis, and can automatically cut a plate flatly placed on a working table at a set angle. When the automatic feeding line 1 works, the automatic feeding line is automatically conveyed to a cutting position, the Y-direction movable beam 10 is driven to move to a set angle according to program setting, and after the material pressing mechanism compresses, the cutting is carried out through the cutting tool 13.

The foregoing embodiments are merely illustrative of the principles and features of this invention, which is not limited to the above-described embodiments, but is capable of various modifications and changes without departing from the spirit and scope of the utility model, which are intended to be within the scope of the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (9)

1. A full-automatic cutting machine is characterized by comprising a main frame, a main upright post, an X-direction fixed beam, an X-direction driving assembly, a Y-direction movable beam, a Y-direction driving assembly, a Z-direction lifting beam, a Z-direction driving assembly, a rotary moving supporting seat, a cutting tool and a material pressing mechanism, wherein a cutting platform is arranged on the end face of the main frame, the main upright post is vertically fixed on the main frame on one side of the cutting platform, the X-direction fixed beam extending along the X-axis direction is fixed on the main frame on the other side, one end of the Y-direction movable beam is assembled at the top of the main upright post through a slewing bearing, a first transition plate is installed at the other end of the Y-direction movable beam, the rotary moving supporting seat is assembled on the X-direction fixed beam, the X-direction driving assembly drives the rotary moving supporting seat to reciprocate along the X-direction, and the bottom surface of the first transition plate is rotatably assembled on the rotary moving supporting seat, the terminal surface can be followed Y axle direction and assembled with moving in Y is to the walking beam, Z to the lifing beam pass through the second cab apron can assemble with going up and down in Y is to the walking beam, Y drives to drive assembly Z is to the lifing beam along Y to reciprocating motion, cut the cutter assembly in Z is to on the lifing beam, Z drives to drive assembly Z is to the lifing beam along Z to reciprocating motion, it is connected with cutter drive arrangement to cut the cutter, swager constructs to compress tightly fixedly to panel on the cutting platform when being configured to cut.

2. The full-automatic cutting machine according to claim 1, wherein an automatic feeding line is arranged at the feeding side of the cutting platform, the automatic feeding line comprises a feeding wire frame, a transmission belt, a driving transmission roller, a driven transmission roller, a servo motor and a side positioning plate, the driving transmission roller and the driven transmission roller are respectively assembled at two ends of the feeding wire frame, the servo motor is in transmission connection with the driving transmission roller through a synchronous belt transmission assembly, and the transmission belt is sleeved on the driving transmission roller and the driven transmission roller.

3. The full-automatic cutting machine according to claim 2, wherein a plurality of support legs are installed at the bottom of the feeding wire frame, wherein the support legs at least one side are detachably fixed on the feeding wire frame through bolts.

4. The automatic cutting machine according to claim 1, wherein a bakelite board is disposed on the cutting platform, and a plurality of through holes are disposed on the bakelite board and communicated with a dust collecting cover under the table top.

5. The full-automatic cutting machine according to claim 1, wherein the pressing mechanism comprises a front pressing frame and a rear pressing frame which are arranged on the Y-direction movable beam, pressing cylinders are arranged on the front pressing frame and the rear pressing frame, and a driving end of each pressing cylinder is connected with a pressing plate.

6. The full-automatic cutting machine according to claim 1, wherein the X-direction driving assembly comprises two X-direction linear guide rails, an X-direction driving rack and an X-direction servo motor, the two X-direction linear guide rails and the X-direction driving rack are parallelly spaced and fixed on the X-direction fixed beam in an extending manner along the X-direction, the bottom of the rotary moving support seat is assembled on the two X-direction linear guide rails through a slider, the X-direction servo motor is fixed on the rotary moving support seat, and a driving gear meshed with the X-direction driving rack is installed at a driving end of the X-direction servo motor.

7. The full-automatic cutting machine according to claim 1, wherein the Y-direction driving assembly comprises two Y-direction linear guide rails, a Y-direction driving rack and a Y-direction servo motor, the two Y-direction linear guide rails and the Y-direction driving rack are fixed on the Y-direction movable beam at intervals in parallel and extend along the Y-direction, the second transition plate is assembled on the two Y-direction linear guide rails through a slider, the Y-direction servo motor is fixed on the second transition plate, and a driving gear meshed with the Y-direction driving rack is installed at a driving end of the Y-direction servo motor.

8. The full-automatic cutting machine according to claim 1, wherein the Z-direction driving assembly comprises two Z-direction linear guide rails, a ball screw, a screw nut and a Z-direction servo motor, the two Z-direction linear guide rails and the ball screw are arranged in parallel at intervals and are assembled on the Z-direction lifting beam in a manner of extending along the Z-direction, the second transition plate is assembled on the two Z-direction linear guide rails and the ball screw through a slider and the screw nut respectively, the Z-direction servo motor is installed at the top of the Z-direction lifting beam, and the driving end of the Z-direction servo motor is connected with the ball screw.

9. The automatic cutting machine according to claim 1, wherein the bottom surface of the first transition plate is mounted on the top of the rotary moving support base through a slewing bearing, and the end surfaces are mounted on two short linear guides fixed on the end of the Y-direction movable beam through a slider.

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