CN211764590U

CN211764590U - Five process numerical control engravers of carpenter

Info

Publication number: CN211764590U
Application number: CN202020289356.2U
Authority: CN
Inventors: 冯世卿
Original assignee: Jinan Pinjia Mechanical Equipment Co ltd
Current assignee: Jinan Pinjia Mechanical Equipment Co ltd
Priority date: 2020-03-11
Filing date: 2020-03-11
Publication date: 2020-10-27
Anticipated expiration: 2030-03-11

Abstract

The utility model discloses a five processes numerical control engravers of carpenter, including the numerical control operation panel, the engraver main part and set up in the workstation on engraver main part upper portion, engraver main part both sides are equipped with the Y axle guide rail of connecting the slip stand, slip stand upper portion fixedly connected with crossbeam, through the X axle guide rail sliding connection host computer that is equipped with on the crossbeam, be equipped with T1 sculpture main shaft on the host computer side by side, T2 sculpture main shaft, T3 sculpture main shaft, T4 sculpture main shaft and T5 sculpture main shaft, T1 sculpture main shaft, T2 sculpture main shaft, T4 sculpture main shaft and T5 sculpture main shaft one side all through sculpture main shaft guide rail sliding connection on Z axle slider, and T1 sculpture main shaft, T2 sculpture main shaft, all be connected with sculpture main shaft cylinder on T4 sculpture main shaft and the T5 sculpture main shaft; the utility model relates to a full-automatic carpenter engraver of five main shafts, the carving tool kind that carries is many, can adapt to all engravings, cutting and the operation of punching that need do in the carpenter's processing.

Description

Five process numerical control engravers of carpenter

Technical Field

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

Background

The engraving machine belongs to modern production equipment, is widely applied to the production and processing processes of various products, the current domestic wood mechanical products for furniture production tend to be high-grade, the wood engraving machine can be applied to the furniture industry, the musical instrument industry, the wood artware industry and the like, and is suitable for engraving and manufacturing large-area plate planes, solid wood furniture, solid wood artistic fresco, density plate paint-free doors and kitchen window doors; there are a few engravers that make multiaxis, like four-axis and triaxial, but degree of automation is low, does not make five-axis engravers, and a main shaft will increase a process more, and five-axis engravers need overcome mechanical structure and electrical control's multiple problem, and the current engraver does not have dust extraction simultaneously, does not have the suction hood to whole panel face or workstation dust absorption more, and operational environment is poor, the polluted environment. Therefore, the design of a five-axis numerical control woodworking engraving machine with a complete dust suction device is a problem to be solved urgently.

SUMMERY OF THE UTILITY MODEL

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

The utility model provides a technical scheme that its technical problem adopted is: a five-procedure numerical control engraving machine for woodworkers comprises a numerical control operation table, an engraving machine main body and a workbench arranged on the upper portion of the engraving machine main body, wherein Y-axis guide rails connected with sliding upright posts are arranged on two sides of the engraving machine main body, the upper portions of the sliding upright posts are fixedly connected with cross beams, the cross beams are connected with a working main machine in a sliding mode through X-axis guide rails, the working main machine is provided with a T1 engraving main shaft, a T2 engraving main shaft, a T3 engraving main shaft, a T4 engraving main shaft and a T5 engraving main shaft side by side, the T1 engraving main shaft, the T2 engraving main shaft, a T4 engraving main shaft and one side of the T5 engraving main shaft are connected onto a Z-axis sliding block through engraving main shaft guide rails in a sliding mode, and engraving main shaft cylinders are connected onto the T1 engraving;

the X-axis sliding block is arranged on the working host and is connected with the X-axis guide rail in a sliding mode, the dust suction box of the dust suction device is arranged on the upper portion of the X-axis sliding block, five main shaft dust suction ports are correspondingly arranged on the lower portion of the dust suction box, a dust suction cover dust suction port and a dust outlet are arranged on the upper portion of the dust suction box, and the dust suction cover dust suction port is connected with a dust suction cover arranged on the lower portion of the cross beam through a dust suction hose.

Specifically, the X-axis sliding block is vertically provided with a Z-axis guide rail, the Z-axis guide rail is connected with a Z-axis sliding block in a sliding mode, and the X-axis sliding block and the Z-axis sliding block are driven by a servo motor.

Specifically, the lower parts of the T1 carving main shaft, the T2 carving main shaft, the T3 carving main shaft, the T4 carving main shaft and the T5 carving main shaft are respectively provided with carving knives of different models, and the T3 carving main shaft positioned in the middle is lower than the T1 carving main shaft, the T2 carving main shaft, the T4 carving main shaft and the T5 carving main shaft.

Specifically, the main body of the engraving machine is provided with an auxiliary roller for auxiliary feeding on one side of the workbench, the other side of the main body of the engraving machine is provided with a positioning strip for positioning the plate, and the lower part of the workbench is provided with a vacuum pump for adsorbing and fixing the plate.

Specifically, the sliding upright post is provided with a Y-axis motor for driving the sliding upright post.

The two dust suction covers are communicated with a long-strip-shaped dust suction box parallel to the workbench, the dust suction boxes are connected to the lower portion of the cross beam in a sliding mode through inclined sliding rails, dust suction cover cylinders for controlling the dust suction boxes to move in an inclined mode are arranged at the two ends of each dust suction box, and the dust suction cover cylinders are fixed to the rear portion of the cross beam.

The vacuum cleaner is characterized in that a main shaft dust suction box corresponding to a main shaft dust suction opening is arranged on the T1 carving main shaft, the T2 carving main shaft, the T3 carving main shaft, the T4 carving main shaft and the T5 carving main shaft, the main shaft dust suction box is connected with the main shaft dust suction opening through a dust suction hose, the dust outlet is connected with a dust suction pump through a main dust suction pipe, the main dust suction pipe is supported and fixed through a dust suction support arranged on one side of a cross beam, and a cylinder for controlling the main shaft dust suction opening, a dust suction cover dust suction opening and a dust outlet switch is arranged inside the dust suction box.

Specifically, the numerical control operation table is electrically connected with the engraving machine body.

The utility model discloses following beneficial effect has:

the woodworking five-process numerical control engraving machine designed by the utility model is a full-automatic woodworking engraving machine with five main shafts, the number of the main shafts is large, the types of the carried engraving knives are various, the engraving machine can adapt to all engraving, cutting and punching operations needing to be carried out in woodworking, a machine realizes multiple processing processes, the working efficiency is improved, and the working cost is saved; the designed complete dust suction device sucks dust for each engraving main shaft and dust for the whole working table surface, so that the safety and the sanitation of the working environment of the engraving machine are kept, and meanwhile, a cylinder for controlling a switch is arranged in the dust suction box, so that the backflow of fragments caused by the fact that the main shaft does not work is avoided; the sculpture main shaft in the middle of the design is less than other sculpture main shafts, saves a sculpture main shaft cylinder, and when other sculpture main shafts were out of work and get back to upper portion, the sculpture main shaft in the middle of worked under the drive of Z axle slider work, and the design is more reasonable, and the practicality is stronger.

Drawings

Fig. 1 is a schematic structural diagram of a woodworking five-process numerical control engraving machine.

Fig. 2 is a front view of the woodworking five-process numerical control engraving machine.

Fig. 3 is a rear view of the woodworking five-process numerical control engraving machine.

Fig. 4 is a left side view of the woodworking five-process numerical control engraving machine.

Fig. 5 is a right side view of the woodworking five-process numerical control engraving machine.

Fig. 6 is an attached view of the woodworking five-process numerical control engraving machine.

In the figure: 1-a main body of the engraving machine; 2-a working host; 3-a dust suction device; 4-a workbench; 5-auxiliary rollers; 6-positioning strips; 7-sliding upright posts; 8-a cross beam; 201-T1 carving the main shaft; 202-T2 carving the main shaft; 203-T3 engraving a main shaft; 204-T4 engraving the main shaft; 205-T5 engraving a main shaft; 206-X axis guide rail; 207-X axis slide; 208-Y-axis guide rails; 209-Z axis guide rails; 210-Z axis slide block; 211-engraving the spindle guide; 212 engraving a main shaft cylinder; 213-graver; a 214-Y axis motor; 301-dust box; 302-spindle suction box; 303-main shaft dust suction port; 304-a dust hood; 305-a suction hood suction opening; 306-a suction hood cylinder; 307-a dust outlet; 308-dust suction support.

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 woodworking five-working-procedure numerical control engraving machine comprises a numerical control operation table, an engraving machine main body 1 and a workbench 4 arranged on the upper part of the engraving machine main body 1, wherein Y-axis guide rails 208 connected with sliding upright posts 7 are arranged on two sides of the engraving machine main body 1, a Y-axis motor 214 for driving the sliding upright posts 7 is arranged on the sliding upright posts 7 and used for driving the whole equipment to move along the Y-axis guide rails 208, a cross beam 8 is fixedly connected on the upper parts of the sliding upright posts 7, the cross beam 8 is connected with a working host machine 2 in a sliding manner through an X-axis guide rail 206, an X-axis slider 207 arranged on the working host machine 2 is connected with an X-axis guide rail 206 in a sliding manner, a Z-axis guide rail 209 is vertically arranged on the X-axis slider 207, a Z-axis slider 210 is connected on the Z-axis guide rail 209 in a sliding, the Z-axis slider 210 moves along the Z-axis guide 209. A T1 carving main shaft 201, a T2 carving main shaft 202, a T3 carving main shaft 203, a T4 carving main shaft 204 and a T5 carving main shaft 205 are arranged on the working host machine 2 side by side, one sides of the T1 carving main shaft 201, the T2 carving main shaft 202, the T4 carving main shaft 204 and the T5 carving main shaft 205 are connected to a Z-axis sliding block 210 in a sliding mode through a carving main shaft guide rail 211, and carving main shaft cylinders 212 are connected to the T1 carving main shaft 201, the T2 carving main shaft 202, the T4 carving main shaft 204 and the T5 carving main shaft 205; the lower parts of the T1 carving main shaft 201, the T2 carving main shaft 202, the T3 carving main shaft 203, the T4 carving main shaft 204 and the T5 carving main shaft 205 are respectively provided with carving knives 213 of different models, the middle T3 carving main shaft 203 is lower than the T1 carving main shaft 201, the T2 carving main shaft 202, the T4 carving main shaft 204 and the T5 carving main shaft 205, the middle carving main shaft is lower than other carving main shafts, one carving main shaft cylinder 212 is saved, when other carving main shafts do not work and return to the upper part, the middle T3 carving main shaft 203 is driven by the Z-axis sliding block 210 to work, the design is more reasonable, and the practicability is higher.

The upper part of the X-axis sliding block 207 is provided with a dust collection box 301 of the dust collection device 3, the lower part of the dust collection box 301 is correspondingly provided with five main shaft dust collection ports 303, the T1 carving main shaft 201, the T2 carving main shaft 202, the T3 carving main shaft 203, the T4 carving main shaft 204 and the T5 carving main shaft 205 are respectively provided with a main shaft dust collection box 302 corresponding to the main shaft dust collection ports 303, and the main shaft dust collection box 302 is connected with the main shaft dust collection ports 303 through a dust collection hose. The upper portion of the dust collection box 301 is provided with a dust collection cover dust collection port 305 and a dust outlet 307, the dust collection cover dust collection port 305 is connected with a dust collection cover 304 arranged on the lower portion of the cross beam 8 through a dust collection hose, the number of the dust collection cover 304 is two, the front portions of the two dust collection covers 304 are communicated with a long strip-shaped dust collection box parallel to the workbench 4, the dust collection box is connected to the lower portion of the cross beam 8 through an oblique sliding rail in a sliding mode, two ends of the dust collection box are provided with dust collection cover air cylinders 306 for controlling the dust collection box to move obliquely, and the dust collection cover air cylinders 306 are fixed to the. The dust outlet 307 is connected with a dust suction pump through a main dust suction pipeline, the main dust suction pipeline is supported and fixed through a dust suction support 308 arranged on one side of the cross beam 8, and a cylinder for controlling the opening and closing of the main shaft dust suction port 303, the dust suction cover dust suction port 305 and the dust outlet 307 is arranged in the dust suction box 301. The designed complete dust suction device 3 sucks dust for each engraving main shaft and dust for the whole 4 surfaces of the workbench, so that the safety and the sanitation of the working environment of the engraving machine are kept, and meanwhile, a cylinder for controlling a switch is arranged in the dust suction box 301, so that the phenomenon that chips flow back when the main shaft does not work is avoided.

Be equipped with supplementary material loading's supplementary gyro wheel 5 on engraver main part 1 in workstation 4 one side for supplementary operating personnel goes up panel, and the opposite side is equipped with the location strip 6 to panel location, and 4 lower parts of workstation are equipped with the vacuum pump that adsorbs fixed panel, realize fixed to panel.

The numerical control operation panel electric connection engraver body 1, and the host computer 2, dust absorption pump and the vacuum pump etc. that set up on the engraver body 1, for example drive X axle slider 207 and Z axle slider 210 servo motor, Y axle motor 214, suction box 301, sculpture main shaft cylinder 212, suction hood cylinder 306 and location strip drive cylinder.

When the utility model is used, a worker turns on a power supply, places a plate on the auxiliary idler wheel 5, pushes the plate onto the workbench 4 by means of sliding labor-saving operation, sets positioning operation on the numerical control operation table, the positioning strip 6 can be automatically lifted, positions the plate close to the right positioning strip 6, simultaneously turns on a vacuum pump, and adsorbs and fixes the plate; then, a numerical control operation table is set according to the requirements for carving, cutting or punching, then the corresponding T1 carving main shaft 201, T2 carving main shaft 202, T4 carving main shaft 204 or T5 carving main shaft 205 moves downwards under the driving of the carving main shaft cylinder 212, at this time, the servo motor controls the Z-axis sliding block 210 to move, the carving, cutting or punching is completed, when the carving main shaft is replaced, the corresponding carving main shaft cylinder 212 performs lifting and descending operations, when the T3 carving main shaft 203 is required to work, other working main shafts return to the uppermost part under the driving of the carving main shaft cylinder 212, the T3 carving main shaft 203 completes the work under the condition that the servo motor drives the Z-axis sliding block 210 to move, and the carving, cutting or punching is completed; meanwhile, the corresponding spindle dust collection box 302 in the dust collection device 3 performs dust collection, and after the operation of the whole plate surface is completed, the dust collection cover cylinder 306 drives the dust collection box to move obliquely downwards, so that a dust collection opening at the lower part is close to the plate, and the dust collection of the scraps on the whole plate surface is completed; work is accomplished, through numerical control operation panel control each part playback, closes the power at last, the utility model discloses the full-automatic carpenter engraver of five main shafts, main shaft in large quantity, the carving tool kind of carrying is many, can adapt to all engravings, cutting and the operation of punching that need do in the wood working, and a tractor serves and realizes multichannel manufacturing procedure, improves work efficiency, saves working cost.

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

1. The utility model provides a five processes numerical control engravers of carpenter which characterized in that: the engraving machine comprises a numerical control operation table, an engraving machine body and a workbench arranged on the upper portion of the engraving machine body, wherein Y-axis guide rails connected with sliding upright posts are arranged on two sides of the engraving machine body, cross beams are fixedly connected to the upper portions of the sliding upright posts, X-axis guide rails arranged on the cross beams are connected with a working host in a sliding mode, a T1 engraving main shaft, a T2 engraving main shaft, a T3 engraving main shaft, a T4 engraving main shaft and a T5 engraving main shaft are arranged on the working host side by side, one sides of the T1 engraving main shaft, the T2 engraving main shaft, the T4 engraving main shaft and the T5 engraving main shaft are connected to a Z-axis sliding block in a sliding mode through the engraving main shaft guide rails, and engraving main shaft cylinders are connected to the T1 engraving main shaft;

2. The five-process numerical control woodworking engraving machine according to claim 1, wherein: and a Z-axis guide rail is vertically arranged on the X-axis slide block, a Z-axis slide block is connected to the Z-axis guide rail in a sliding manner, and the X-axis slide block and the Z-axis slide block are driven by a servo motor.

3. The five-process numerical control woodworking engraving machine according to claim 1, wherein: the lower parts of the T1 carving main shaft, the T2 carving main shaft, the T3 carving main shaft, the T4 carving main shaft and the T5 carving main shaft are respectively provided with carving knives of different models, and the T3 carving main shaft positioned in the middle is lower than the T1 carving main shaft, the T2 carving main shaft, the T4 carving main shaft and the T5 carving main shaft.

4. The five-process numerical control woodworking engraving machine according to claim 1, wherein: the engraving machine is characterized in that an auxiliary roller for auxiliary feeding is arranged on one side of the workbench on the engraving machine main body, a positioning strip for positioning the plate is arranged on the other side of the workbench, and a vacuum pump for adsorbing and fixing the plate is arranged on the lower portion of the workbench.

5. The five-process numerical control woodworking engraving machine according to claim 1, wherein: and a Y-axis motor for driving the sliding upright post is arranged on the sliding upright post.

6. The five-process numerical control woodworking engraving machine according to claim 1, wherein: the two dust hoods are provided, the front parts of the two dust hoods are communicated with a long-strip-shaped dust box parallel to the workbench, the dust box is connected to the lower part of the cross beam through an inclined sliding rail in a sliding manner, two ends of the dust box are provided with dust hood cylinders for controlling the dust box to move obliquely, and the dust hood cylinders are fixed to the rear part of the cross beam.

7. The five-process numerical control woodworking engraving machine according to claim 6, wherein: t1 sculpture main shaft, T2 sculpture main shaft, T3 sculpture main shaft, all be equipped with the main shaft dust absorption box that corresponds with the main shaft dust absorption mouth on T4 sculpture main shaft and the T5 sculpture main shaft, and the main shaft dust absorption box passes through the dust absorption hose with the main shaft dust absorption mouth and is connected, the dust outlet passes through the dust absorption trunk line and connects the dust absorption pump, the dust absorption trunk line supports fixedly through the dust absorption support of installing in crossbeam one side, the inside cylinder that is equipped with control main shaft dust absorption mouth, suction hood dust absorption mouth and dust outlet switch of suction box.

8. The five-process numerical control woodworking engraving machine according to claim 1, wherein: the numerical control operation panel is electrically connected with the engraving machine body.