CN212331323U - Woodworking double-gantry numerical control engraving machine - Google Patents

Abstract

The utility model discloses a woodworking double-gantry numerical control engraving machine, which comprises a front working host, a rear working host, a material turning device and a label printer, wherein the material turning device and the label printer are installed on the rear working host; the front working host comprises a cutting host portal frame, a cutting host, a cutting workbench, a cutting centering mechanism, a cutting feeding mechanism, a cutting dust collection mechanism and a tool magazine, and the rear working host comprises a rear host portal frame, a rear host, a rear workbench, a rear centering mechanism, a rear feeding mechanism and a rear dust collection mechanism; the utility model discloses a preceding work host computer and back work host computer realize punching the grooving and the cutting goes on simultaneously to still be equipped with automatic feeding, stirring, location and unloading mechanism, automatic level is high, uses manpower sparingly, avoids the manpower potential safety hazard, improves work efficiency.

Description

Woodworking double-gantry numerical control engraving machine

Technical Field

The utility model relates to an engraver technical field, concretely relates to two longmen numerical control engravers of carpenter.

Background

The engraving machine belongs to a modernized production facility, the wide application has been in the production course of working of various products, the present domestic wood working machine product that is used for furniture production is tending towards the high-grade, the wood engraving machine can be applied to furniture trade, musical instrument trade and wooden handicraft trade etc., and be applicable to large tracts of land panel plane, wood furniture, wood art mural painting, the lacquer door is exempted from to density board and kitchen window door sculpture and preparation, the wood engraving machine that commonly uses on the market now is mostly unipolar operation, only have a portal frame to carry a sculpture main shaft promptly, the during operation or only can carry out the cutting operation, or only can carry out the grooving operation of punching, when needing to cut or making different work holes, still need the manual work to change the carving tool, waste time and energy. And need the manual work go on go up unloading and turn over the board work, a panel punches and grooving operation completion back on a machine, needs the manual work to carry out the unloading, carries out cutting work on transporting another machine, and artifical intensity of labour is big, and work efficiency is very low, and there is great potential safety hazard in manual work. Therefore, the design of a woodworking double-gantry numerical control engraving machine is urgently needed to solve the problems that the existing engraving machine only has a single gantry, the automation degree is low and the working efficiency is low.

SUMMERY OF THE UTILITY MODEL

To the problem that exists among the prior art, the utility model aims to provide a two longmen numerical control engravers of carpenter.

The utility model provides a technical scheme that its technical problem adopted is: a woodworking double-gantry numerical control engraving machine comprises a front working host, a rear working host, a material turning device and a label printer, wherein the material turning device and the label printer are installed on the rear working host;

the cutting machine comprises a front working host, a cutting main machine, a cutting main shaft, a cutting centering mechanism, a cutting side centering cylinder and a cutting side centering cylinder, wherein two sides of the front working host are provided with cutting Y-axis slide rails, the cutting Y-axis slide rails are connected with cutting Y-axis slide blocks in a sliding manner, two cutting Y-axis slide blocks are connected with a cutting main machine portal frame, the cutting main machine portal frame is connected with the cutting main machine in a sliding manner, the cutting main shaft is arranged on the cutting main machine and used for cutting plates, a cutting workbench is arranged below the cutting main machine and at the top of the front working host, the front part and one side of the cutting workbench are provided with a plurality of cutting telescopic stop rods of the cutting centering mechanism, the cutting telescopic stop rods are arranged on cylinder rods of the cutting telescopic cylinder and used for stopping the front part and the side of the plates, the cutting centering, the cutting machine comprises a cutting main machine portal frame, a cutting machine, a feeding mechanism, a cutting machine;

rear Y-axis slide rails are arranged on two sides of the rear working host, rear Y-axis slide rails are connected with rear Y-axis slide blocks in a sliding manner, a rear host portal frame is connected onto the two rear Y-axis slide blocks, a rear host is connected onto the rear host in a sliding manner, a plurality of punching and grooving main shafts are mounted on the rear host and are used for punching and grooving plates, a rear workbench is arranged below the rear host and at the top of the rear working host, a plurality of rear telescopic stop levers of a rear centering mechanism are mounted on the front part and one side of the rear workbench, the rear telescopic stop levers are mounted on cylinder rods of the rear telescopic cylinder and are used for stopping the front part and the side surfaces of the plates, a rear centering cylinder is mounted in the middle of an auxiliary feeding plate by the rear centering mechanism and is used for pushing the rear part of the plates and pushing the front end of the plates onto the rear telescopic stop levers at the front end, rear feeding lifting cylinders of the rear loading mechanism are mounted on two sides of the rear part of the rear host portal frame, the device is used for adsorbing the plates and conveying the plates to a rear workbench through a rear host portal frame, and a feeding lifting frame is arranged behind the rear host for placing the plates and allowing a rear feeding negative pressure sucker to adsorb the plates to the rear workbench;

one side of the rear working host is provided with a material overturning device which is fixed on the ground through an arranged material overturning bracket, one side of the material overturning bracket close to the rear working host is rotatably connected with a synchronizing shaft, the synchronizing shaft is fixedly provided with a material overturning mechanical arm, the material overturning mechanical arm is symmetrically provided with two material clamping cylinders, the end part of the material overturning mechanical arm, which is opposite to the material clamping cylinders, is provided with a stop block, used for clamping plates to complete overturning and turning, the middle part of the synchronizing shaft is provided with a turning driving motor used for driving the synchronizing shaft to rotate to drive the turning mechanical arm to rotate, the turning support is also rotatably connected with a linkage shaft, two ends of the linkage shaft are connected with synchronous belts arranged at two sides of the turning support in a driving way, one end of the linkage shaft is connected with a feeding driving motor, and the centering cylinders are arranged on two sides of the turnover support and used for centering the top of the turnover plate.

Specifically, the cutting host portal frame both sides are installed on cutting Y axle slider through the cutting stand that is equipped with, be connected with the cutting crossbeam between two cutting stands, transversely install cutting X axle slide rail on the cutting crossbeam, sliding connection has cutting X axle slide and cutting X axle servo motor on the cutting X axle slide rail, be equipped with vertical cutting Z axle slide rail on the cutting X axle slide rail, sliding connection has cutting Z axle slide on the cutting Z axle slide rail, install cutting Z axle servo motor on the cutting Z axle slide, install the cutting main shaft of connecting cutting Z axle servo motor on the cutting Z axle slide.

Specifically, a cutting Y-axis servo motor is mounted on the cutting Y-axis sliding block and used for driving the cutting host portal frame to move along the direction of the cutting Y-axis sliding rail.

Specifically, a tool magazine for storing a plurality of cutting tools is arranged below the cutting main shaft and on the cutting cross beam and used for finishing the cutting requirements of different plates.

The rear main engine portal frame comprises a rear main engine portal frame body, rear columns are arranged on two sides of the rear main engine portal frame body, a rear cross beam is connected between the two rear columns, a rear X-axis slide rail is transversely arranged on the rear cross beam, a rear X-axis slide plate and a rear X-axis servo motor are connected on the rear X-axis slide rail in a sliding mode, a vertical rear Z-axis slide rail is arranged on the rear X-axis slide plate, a rear Z-axis slide plate is connected on the rear Z-axis slide rail in a sliding mode, and a rear Z-axis servo motor is arranged on the rear Z-axis slide plate and used for driving the rear Z-axis slide.

Specifically, four main shaft slide rails are vertically installed on the rear Z-axis slide plate, a punching main shaft is connected to the main shaft slide rails in a sliding mode, a driving cylinder for driving the punching main shaft to move up and down is connected to the upper portion of the punching main shaft, and a saw blade main shaft is installed beside the punching main shaft and on the rear Z-axis slide plate and used for grooving on the plate.

Specifically, a rear Y-axis servo motor is mounted on the rear Y-axis sliding block and used for driving the rear host portal frame to move along the direction of the rear Y-axis sliding rail.

Specifically, the label printer is arranged on a rear host portal frame through a support and used for printing labels on the plates.

Specifically, a cutting dust suction mechanism is installed on the cutting main machine, and a rear dust suction mechanism is installed on the rear main machine.

The utility model discloses following beneficial effect has:

the woodworking double-gantry numerical control engraving machine realizes simultaneous punching, grooving and cutting through the front working host and the rear working host, is also provided with an automatic feeding mechanism, a material turning mechanism, a positioning mechanism and a discharging mechanism, has high automation level, saves manpower, avoids manpower potential safety hazard, improves the working efficiency, and realizes the processing of 150 plates in one machine per day; the two designed working hosts carry out automatic feeding through the negative pressure sucker, so that automatic feeding is realized, and punching, grooving and cutting are carried out simultaneously; the designed material turning device realizes automatic turning of the plate, realizes all-dimensional punching and grooving on two surfaces of the plate, and completes processing of the plate all-dimensionally at one time; the designed centering mechanism realizes the centering of the plate, and ensures the accuracy of the punching, grooving and cutting work; the label printer of design realizes automatic labelling, avoids artifical the subsides, improves work efficiency.

Drawings

FIG. 1 is a schematic structural diagram of a woodworking double-gantry numerical control engraving machine.

Fig. 2 is a front view of the woodworking double gantry numerically controlled engraving machine.

FIG. 3 is a top view of a woodworking double gantry numerically controlled engraving machine.

FIG. 4 is a right side view of a woodworking double gantry numerically controlled engraving machine.

Fig. 5 is a left side view of the woodworking double gantry numerically controlled engraving machine.

Fig. 6 is a bottom view of the woodworking double gantry numerically controlled engraving machine.

In the figure: 1-front working host; 2-rear working host; 3-a material turning device; 4-a label printer; 5-auxiliary feeding plate; 6-auxiliary pulley; 1.1-cutting a host portal frame; 1.2-cutting the host; 1.3-cutting table; 1.4-cutting centering mechanism; 1.5-cutting and feeding mechanism; 1.6-cutting dust-absorbing mechanism; 1.7-tool magazine; 1.1.1-cutting a Y-axis slide rail; 1.1.2-cutting the Y-axis slide block; 1.1.3-cutting Y-axis servo motor; 1.1.4-cutting the upright column; 1.1.5-cutting the beam; 1.1.6-cutting the X-axis slide rail; 1.2.1-cutting an X-axis servo motor; 1.2.2-cutting the Z-axis slide rail; 1.2.3-cutting the Z-axis slide plate; 1.2.4-cutting a Z-axis servo motor; 1.2.5-cutting the main shaft; 1.4.1-cutting the telescopic stop lever; 1.4.2-centering the cylinder after cutting; 1.5.1-cutting and feeding lifting cylinder; 1.5.2-cutting and loading negative pressure sucker; 2.1-rear host gantry; 2.2-rear host; 2.3-rear working table; 2.4-rear centering mechanism; 2.5-rear feeding mechanism; 2.6-rear dust suction mechanism; 2.1.1-rear Y-axis slide rail; 2.1.2-rear Y-axis slide block; 2.1.3-rear Y-axis servo motor; 2.1.4-rear column; 2.1.5-rear beam; 2.1.6-rear X-axis slide rail; 2.2.1-rear X-axis servo motor; 2.2.2-rear Z-axis slide rail; 2.2.3-rear Z-axis slide plate; 2.2.4-rear Z-axis servo motor; 2.2.5-main shaft of punching and grooving; 2.4.1-rear telescopic stop lever; 2.4.2-rear centering cylinder; 2.5.1-rear feeding lifting cylinder; 2.5.2-back feeding negative pressure sucker; 3.1-a material turning support; 3.2-a material turning mechanical arm; 3.3-a material turning driving motor; 3.4-linkage shaft; 3.5-material clamping cylinder; 3.6-stop block; 3.7-feeding driving motor; 3.8-synchronizing shaft; 3.9-synchronous belt; 3.10-centering the cylinder.

Detailed Description

The technical solution in the embodiments of the present invention will be described in further detail in the following clearly and completely with reference to the accompanying drawings in the embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1-6, a carpenter's two gantry numerical control engravers, including preceding work host computer 1, back work host computer 2 and install stirring device 3 and label printer 4 on back work host computer 2, connect through supplementary flitch 5 of going up between preceding work host computer 1 and the back work host computer 2, preceding work host computer 1 all is equipped with supplementary flitch 5 of going up with 2 rear ends of back work host computer, be equipped with a plurality of supplementary pulleys 6 on supplementary flitch 5 of going up, a material loading for supplementary panel, label printer 4 passes through the support mounting on back host computer portal frame 2.1, a label is printed on panel, realize automatic labeling, avoid artifical the subsides, and work efficiency is improved.

The front working host 1 comprises a cutting host portal frame 1.1, a cutting host 1.2, a cutting workbench 1.3, a cutting centering mechanism 1.4, a cutting feeding mechanism 1.5, a cutting dust absorption mechanism 1.6 and a tool magazine 1.7. Two sides of a front working host 1 are provided with cutting Y-axis slide rails 1.1.1, the cutting Y-axis slide rails 1.1.1 are connected with cutting Y-axis slide blocks 1.1.2 in a sliding manner, two cutting Y-axis slide blocks 1.1.2 are connected with a cutting host portal frame 1.1, the cutting host portal frame 1.1 is connected with a cutting host 1.2 in a sliding manner, a cutting spindle 1.2.5 is mounted on the cutting host 1.2 and used for cutting plates, two sides of the cutting host portal frame 1.1 are mounted on the cutting Y-axis slide blocks 1.1.2 through cutting upright columns 1.1.4, and cutting Y-axis servo motors 1.1.3 are mounted on the cutting Y-axis slide blocks 1.1.2 and used for driving the cutting host portal frame 1.1 to move along the direction of the cutting Y-axis slide rails 1.1.1.1. A cutting beam 1.1.5 is connected between the two cutting columns 1.1.4, a cutting X-axis slide rail 1.1.6 is transversely installed on the cutting beam 1.1.5, a cutting X-axis slide plate and a cutting X-axis servo motor 1.2.1 are connected on the cutting X-axis slide rail 1.1.6 in a sliding manner and used for driving the cutting X-axis slide plate to transversely move along the direction of the cutting X-axis slide rail 1.1.6, a vertical cutting Z-axis slide rail 1.2.2 is arranged on the cutting X-axis slide plate, a cutting Z-axis slide plate 1.2.3 is connected on the cutting Z-axis slide rail 1.2.2 in a sliding manner and used for driving the cutting main shaft 1.2.5 to move up and down along the direction of the cutting Z-axis slide rail 1.2.2. A tool magazine 1.7 for storing a plurality of cutting tools is arranged below the cutting main shaft 1.2.5 and on the cutting beam 1.1.5 and used for finishing the cutting requirements of different plates.

A cutting working table 1.3 is arranged below a cutting main machine 1.2 and at the top of a front working main machine 1, a plurality of cutting telescopic stop levers 1.4.1 of a cutting centering mechanism 1.4 are arranged at the front part and one side of the cutting working table 1.3, the cutting telescopic stop levers 1.4.1 are arranged on cylinder rods of the cutting telescopic cylinders and are used for stopping the front part and the side surface of a plate, a cutting centering cylinder 1.4.2 is arranged in the middle of an auxiliary feeding plate 5 of the cutting centering mechanism 1.4 and is used for supporting the rear part of the plate and pushing the front end of the plate to the cutting telescopic stop lever 1.4.1 at the front end, a cutting side centering cylinder is arranged at one side of a portal frame 1.1 opposite to the cutting telescopic stop levers 1.4.1 and is used for supporting one side of the plate and pushing the other side of the plate to the cutting telescopic stop lever 1.4.1 at the side, cutting feeding lifting cylinders 1.5.1 of the cutting feed mechanism 1.5 are arranged at the two sides of the rear part of the portal frame 1.1.1, a negative pressure suction cup 2 is arranged at the lower part of the cutting feed lifting cylinder 1.5, the adsorption plate is conveyed to the cutting workbench 1.3 through the cutting host portal frame 1.1.

The rear working host 2 comprises a rear host portal frame 2.1, a rear host 2.2, a rear workbench 2.3, a rear centering mechanism 2.4, a rear feeding mechanism 2.5 and a rear dust absorption mechanism 2.6. Rear Y-axis slide rails 2.1.1 are arranged on two sides of the rear working host 2, a rear Y-axis slide block 2.1.2 is connected onto the rear Y-axis slide rails 2.1.1 in a sliding mode, and a rear Y-axis servo motor 2.1.3 is installed on the rear Y-axis slide block 2.1.2 and used for driving the rear host portal frame 2.1 to move along the direction of the rear Y-axis slide rails 2.1.1. The back of the two back Y-axis sliding blocks 2.1.2 is connected with a back host machine portal frame 2.1, the back host machine portal frame 2.1 is connected with a back host machine 2.2 in a sliding way, a plurality of punching and grooving main shafts 2.2.5 are arranged on the back host machine 2.2, used for punching and grooving plates, two sides of a rear host portal frame 2.1 are arranged on a rear Y-axis slide block 2.1.2 through rear upright posts 2.1.4, a rear cross beam 2.1.5 is connected between the two rear upright posts 2.1.4, a rear X-axis slide rail 2.1.6 is transversely arranged on the rear cross beam 2.1.5, a rear X-axis slide plate and a rear X-axis servo motor 2.2.1 are slidably connected on the rear X-axis slide rail 2.1.6, used for driving the rear X-axis sliding plate to transversely move along the direction of a rear X-axis sliding rail 2.1.6, a vertical rear Z-axis sliding rail 2.2.2 is arranged on the rear X-axis sliding plate, the rear Z-axis sliding rail 2.2.2 is connected with a rear Z-axis sliding plate 2.2.3 in a sliding way, a rear Z-axis servo motor 2.2.4 is arranged on the rear Z-axis sliding plate 2.2.3, used for driving the rear Z-axis sliding plate 2.2.3 to move up and down along the rear Z-axis sliding rail 2.2.2. Four main shaft slide rails are vertically installed on the rear Z-axis sliding plate 2.2.3, a punching main shaft is connected to the main shaft slide rails in a sliding mode, a driving cylinder for driving the punching main shaft to move up and down is connected to the upper portion of the punching main shaft, and a saw blade main shaft is installed beside the punching main shaft and on the rear Z-axis sliding plate 2.2.3 and used for grooving on the plate.

A rear working table 2.3 is arranged below the rear main machine 2.2 and at the top of the rear working main machine 2, a plurality of rear telescopic stop levers 2.4.1 of a rear centering mechanism 2.4 are arranged at the front part and one side of the rear working table 2.3, the rear telescopic stop levers 2.4.1 are arranged on cylinder rods of a rear telescopic cylinder, used for blocking the front part and the side surface of the plate, a rear centering mechanism 2.4 is provided with a rear centering cylinder 2.4.2 in the middle of an auxiliary feeding plate 5, a rear telescopic stop lever 2.4.1 used for oppositely propping the rear part of the plate and propping and arranging the front end of the plate on the front end, rear feeding lifting cylinders 2.5.1 of a rear feeding mechanism 2.5 are arranged on two sides of the rear part of a rear host portal frame 2.1, a rear feeding negative pressure suction cup 2.5.2 is arranged on the lower part of a cylinder rod of the rear feeding lifting cylinder 2.5.1, is used for conveying the adsorption plates to a rear workbench 2.3 through a rear main machine portal frame 2.1, a feeding lifting frame is arranged at the rear part of the rear main machine 2, the plate placing device is used for placing plates and enabling the rear feeding negative pressure sucker 2.5.2 to adsorb the plates to the rear workbench 2.3.

A material turning device 3 is arranged at one side of the rear working host 2, the material turning device 3 is fixed on the ground through a material turning support 3.1, a synchronizing shaft 3.8 is rotatably connected at one side of the material turning support 3.1 close to the rear working host 2, a material turning mechanical arm 3.2 is fixedly arranged on the synchronizing shaft 3.8, two material clamping cylinders 3.5 are symmetrically arranged on the material turning mechanical arm 3.2, a stop block 3.6 is arranged at the end part of the material turning mechanical arm 3.2 opposite to the material clamping cylinder 3.5 and used for clamping a plate to complete turning and turning, a material turning driving motor 3.3 is arranged at the middle part of the synchronizing shaft 3.8 and used for driving the synchronizing shaft 3.8 to rotate to drive the material turning mechanical arm 3.2 to rotate, a linkage shaft 3.4 is also rotatably connected on the material turning support 3.1, two ends of the linkage shaft 3.4 are in centering driving connection with synchronous belts 3.9 arranged at two sides of the material turning support 3.1, a material loading driving motor 3.7 is connected at one end of the linkage shaft 3.4 and used for conveying the turned plate back to the rear working host 2.3, and two, and the device is used for jacking and centering the turned plate. The material overturning device 3 realizes automatic material overturning of the plate, realizes all-around punching and grooving of two surfaces of the plate, and completes processing of the plate in all directions at one time. The punching, grooving and cutting are simultaneously carried out through the front working host 1 and the rear working host 2, and the automatic feeding, turning, positioning and discharging mechanisms are further equipped, so that the automation level is high, manpower is saved, the manpower potential safety hazard is avoided, the working efficiency is improved, and the processing of 150 plates per day by one machine is realized.

A working method of a woodworking double-gantry numerical control engraving machine comprises the following steps:

1) when the automatic zero-point alignment device is used, the front working host 1, the rear working host 2 and the control host are electrified, the front working host 1 and the rear working host 2 automatically perform zero-point alignment, a plate is placed on the feeding lifting frame and works according to set parameters in the control host, and the rear host portal frame 2.1 runs above the feeding lifting frame;

2) the rear feeding lifting cylinder 2.5.1 descends to enable the rear feeding negative pressure sucker 2.5.2 to be vacuumized and adsorbed at one end of the plate, the rear feeding lifting cylinder 2.5.1 ascends, the rear host portal frame 2.1 moves forwards to pull the plate to move to the rear workbench 2.3 through the auxiliary pulley 6, the rear feeding negative pressure sucker 2.5.2 is disconnected to enable the plate to fall onto the rear workbench 2.3, the rear telescopic stop lever 2.4.1 ascends, and the centering cylinder 3.10 and the rear centering cylinder 2.4.2 respectively prop the plate to the rear telescopic stop levers 2.4.1 on the other two sides;

3) punching operation is carried out on the plates by punching main shafts of different models, grooving operation is carried out on a saw blade main shaft, after one surface of each plate is processed, a material turning driving motor 3.3 drives a material turning mechanical arm 3.2 to turn over above the plate, a stop dog 3.6 is positioned on one side of each plate at the moment, a material clamping cylinder 3.5 extends out of each plate to clamp the plate, the material turning driving motor 3.3 drives the plate to turn over a material turning support 3.1, a material loading driving motor 3.7 drives a synchronous belt 3.9 to rotate to convey the plate back to a back workbench 2.3, then the centering cylinder 3.10 and a back centering cylinder 2.4.2 respectively push the plate to back telescopic stop levers 2.4.1 on the other two sides to carry out secondary centering and grooving operation for punching on the other surface of the plate, and a back dust suction mechanism 2.6 carries out negative pressure dust suction operation in the;

4) after punching and grooving are finished, the cutting host portal frame 1.1 moves to the upper side of the plate, the cutting feeding negative pressure sucker 1.5.2 conveys the plate to the cutting workbench 1.3 according to the working principle of the rear feeding negative pressure sucker 2.5.2, the centering cylinder 1.4.2 after cutting and the centering cylinder at the cutting side respectively jack the plate to the cutting telescopic stop levers 1.4.1 at the other two sides, and the plate is centered;

5) then the cutting host 1.2 drives the cutting main shaft 1.2.5 to select a corresponding cutting knife in the tool magazine 1.7 according to the set cutting parameters, the sheet is cut, the cutting dust absorption mechanism 1.6 performs negative pressure dust absorption operation in the process, the cut sheet is subjected to blanking, and the automatic cycle operation is performed in sequence.

The utility model discloses not be limited to above-mentioned embodiment, anybody should learn the structural change who makes under the teaching of the utility model, all with the utility model discloses have the same or close technical scheme, all fall into the utility model discloses an within the protection scope.

The technology, shape and construction parts which are not described in detail in the present invention are all known technology.

Claims (9)

1. A woodworking double-gantry numerical control engraving machine is characterized by comprising a front working host, a rear working host, a material turning device and a label printer, wherein the material turning device and the label printer are installed on the rear working host;

the cutting machine comprises a front working host, a cutting main machine, a cutting main shaft, a cutting centering mechanism, a cutting side centering cylinder and a cutting side centering cylinder, wherein two sides of the front working host are provided with cutting Y-axis slide rails, the cutting Y-axis slide rails are connected with cutting Y-axis slide blocks in a sliding manner, two cutting Y-axis slide blocks are connected with a cutting main machine portal frame, the cutting main machine portal frame is connected with the cutting main machine in a sliding manner, the cutting main machine is provided with the cutting main shaft and is used for cutting plates, a cutting workbench is arranged below the cutting main machine and at the top of the front working host, the front part and one side of the cutting workbench are provided with a plurality of cutting telescopic stop rods of the cutting centering mechanism, the cutting telescopic stop rods are arranged on cylinder rods of the cutting telescopic cylinder and are used for stopping the front part and the side of the plates, the, the cutting machine comprises a cutting main machine portal frame, a cutting machine, a feeding mechanism, a cutting machine;

rear Y-axis slide rails are arranged on two sides of a rear working host, rear Y-axis slide rails are connected on the rear Y-axis slide rails in a sliding manner, a rear host portal frame is connected on the two rear Y-axis slide rails, a rear host is connected on the rear host in a sliding manner, a plurality of punching and grooving main shafts are mounted on the rear host and are used for punching and grooving plates, a rear workbench is arranged below the rear host and at the top of the rear working host, a plurality of rear telescopic stop levers of a rear centering mechanism are mounted on the front part and one side of the rear workbench, the rear telescopic stop levers are mounted on cylinder rods of the rear telescopic cylinder and are used for stopping the front part and the side surfaces of the plates, a rear centering cylinder is mounted in the middle of an auxiliary feeding plate by the rear centering mechanism and is used for propping against the rear part of the plates and propping against the rear telescopic stop levers at the front end, rear feeding lifting cylinders of the rear loading mechanism are mounted on two sides of the rear part of the rear host, a rear feeding, the device is used for adsorbing the plates and conveying the plates to a rear workbench through a rear host portal frame, and a feeding lifting frame is arranged behind the rear host for placing the plates and allowing a rear feeding negative pressure sucker to adsorb the plates to the rear workbench;

one side of the rear working host is provided with a material overturning device which is fixed on the ground through an arranged material overturning bracket, one side of the material overturning bracket close to the rear working host is rotatably connected with a synchronizing shaft, the synchronizing shaft is fixedly provided with a material overturning mechanical arm, the material overturning mechanical arm is symmetrically provided with two material clamping cylinders, the end part of the material overturning mechanical arm, which is opposite to the material clamping cylinders, is provided with a stop block, used for clamping plates to complete overturning and turning, the middle part of the synchronizing shaft is provided with a turning driving motor used for driving the synchronizing shaft to rotate to drive the turning mechanical arm to rotate, the turning support is also rotatably connected with a linkage shaft, two ends of the linkage shaft are connected with synchronous belts arranged at two sides of the turning support in a driving way, one end of the linkage shaft is connected with a feeding driving motor, and the centering cylinders are arranged on two sides of the turnover support and used for centering the top of the turnover plate.

2. The woodworking double-gantry numerical control engraving machine as claimed in claim 1, wherein two sides of the cutting host gantry are mounted on a cutting Y-axis slider through cutting columns, a cutting cross beam is connected between the two cutting columns, a cutting X-axis slide rail is transversely mounted on the cutting cross beam, a cutting X-axis slide plate and a cutting X-axis servo motor are slidably connected onto the cutting X-axis slide rail, a vertical cutting Z-axis slide rail is arranged on the cutting X-axis slide plate, a cutting Z-axis slide plate is slidably connected onto the cutting Z-axis slide rail, a cutting Z-axis servo motor is mounted on the cutting Z-axis slide plate, and a cutting spindle connected with the cutting Z-axis servo motor is mounted on the cutting Z-axis slide plate.

3. The woodworking double-gantry numerical control engraving machine as claimed in claim 2, wherein a cutting Y-axis servo motor is mounted on the cutting Y-axis slider and used for driving the cutting host gantry to move along the direction of the cutting Y-axis slide rail.

4. The woodworking double-gantry numerical control engraving machine as claimed in claim 2, wherein a tool magazine for storing a plurality of cutting tools is mounted below the cutting main shaft and on the cutting cross beam and used for finishing cutting requirements of different plates.

5. The woodworking double-gantry numerical control engraving machine as claimed in claim 1, wherein two sides of the rear main gantry are mounted on a rear Y-axis slide block through rear pillars, a rear cross beam is connected between the two rear pillars, a rear X-axis slide rail is transversely mounted on the rear cross beam, a rear X-axis slide plate and a rear X-axis servo motor are slidably connected onto the rear X-axis slide rail, a vertical rear Z-axis slide rail is arranged on the rear X-axis slide plate, a rear Z-axis slide plate is slidably connected onto the rear Z-axis slide rail, and a rear Z-axis servo motor is mounted on the rear Z-axis slide plate and used for driving the rear Z-axis slide plate to move up and down along the rear Z-axis slide.

6. The woodworking double-gantry numerical control engraving machine as claimed in claim 5, wherein four main shaft sliding rails are vertically mounted on the rear Z-axis sliding plate, a punching main shaft is slidably connected onto the main shaft sliding rails, a driving cylinder for driving the punching main shaft to move up and down is connected to the upper portion of each punching main shaft, and a saw blade main shaft is mounted beside each punching main shaft and on the rear Z-axis sliding plate and used for grooving the plate.

7. The woodworking double-gantry numerical control engraving machine according to claim 5, wherein a rear Y-axis servo motor is mounted on the rear Y-axis slide block and used for driving a rear host gantry to move along the direction of a rear Y-axis slide rail.

8. The woodworking double gantry numerical control engraving machine according to claim 1, wherein the label printer is mounted on the rear host gantry through a bracket and used for printing labels on the plates.

9. The woodworking double-gantry numerical control engraving machine according to claim 1, wherein the cutting main machine is provided with a cutting and dust collecting mechanism, and the rear main machine is provided with a rear dust collecting mechanism.

Images