CN218429257U - Visual bridge cutting machine - Google Patents

Abstract

The utility model relates to a visual bridge cutting machine, including the lathe bed, Y is installed to guide rail and rack at the top of lathe bed, and Y is to the top installation second slider of guide rail, and the crossbeam is installed at the top of second slider, and the drive assembly is installed at the top of crossbeam, and the gear is installed to the output shaft of drive assembly. The beneficial effects of the utility model reside in that, can realize that panel horizontal rip cutting is opened the material, the polygon cutting, the circular arc cutting, 45 chamfer functions are provided, expand the A axle on four-axis bridge cutter basis, can be to panel rip cutting, the chamfer, provide and grab board aversion mechanism, carry out panel aversion to cutting path interference position in the cutting process, avoid extravagant, improve the panel rate of utilization, provide supplementary feed mechanism, the mesa becomes about 85 ~ 87 of horizontal plane angle during the material loading, avoid the cracked problem of board material loading greatly, an intelligent vision operating system is provided, intelligent vision system snatchs the panel size, whether the analysis has the defect, intelligent composing, panel automatic aversion avoids interfering.

Description

Visual bridge cutting machine

Technical Field

The utility model relates to a bridge cutter technical field especially relates to a visual bridge cutter.

Background

Along with social development, people increasingly accept natural beauty to decoration styles, people can naturally beauty at home, people can live at the same time, the acceptance degree of stone decoration is higher and higher, common stone slabs comprise natural stones, artificial marbles, rock slabs and the like, the stone slabs with the length and width specifications exceeding 3200 multiplied by 2000 are conventionally called as large slabs, and the processing flow of the stone slabs at present is as follows: the method comprises the steps of large plate-specification plate-forming-grinding-polishing-warehousing, wherein the large plate is processed until the specification plate is cut by a bridge cutting machine, and the thin stone plate needs to be vertically and slightly obliquely placed when being stacked in a large area, so that the plate can be prevented from being broken and cracked to the maximum extent. The bridge cutting machine often cracks when the stone is loaded on the board in the process of cutting the board, and the adjacent boards are damaged by over-cutting in the cutting process, so that the boards are difficult to position on the table board and the like.

SUMMERY OF THE UTILITY MODEL

In view of the above-mentioned problems in the prior art, the main object of the present invention is to provide a visual bridge cutting machine.

The technical scheme of the utility model is like this: the utility model provides a visual bridge cutting machine, includes the lathe bed, Y is installed to the top of lathe bed to guide rail and rack, Y is to the top installation second slider of guide rail, the crossbeam is installed at the top of second slider, drive assembly is installed at the top of crossbeam, the gear is installed to drive assembly's output shaft, X is all installed to the top and the outside of crossbeam to the guide rail, the top installation rack of crossbeam, the gear is connected with the meshing of rack, X is provided with first slider to the top of guide rail.

In a preferred embodiment, the drive assembly is formed by combining a servo motor and a speed reducer.

In a preferred embodiment, an X-axis sliding plate assembly is mounted at the top of the machine bed, and the X-axis sliding plate assembly is connected with a driving assembly.

As a preferred embodiment, the X-axis slide assembly is connected to the first slide block, a ball screw assembly is disposed on one side of the X-axis slide assembly, a screw nut of the ball screw assembly is fixedly connected to the X-axis slide assembly, a Z-direction slide assembly is mounted on the top of the bed, a Z-direction guide rail is disposed on the top of the Z-direction slide assembly, and a screw rod of the ball screw assembly is fixedly connected to the Z-direction slide assembly.

In a preferred embodiment, the top end of the X-axis sliding plate assembly is connected with a driving assembly, and an output shaft of the driving assembly is connected with the shaft end of the ball screw assembly through a coupling.

In a preferred embodiment, a C-axis speed reducer is mounted on an outer wall of the Z-direction sliding plate assembly, a C-axis motor is mounted at an input end of the C-axis speed reducer, and a mounting seat is mounted at an output end of the C-axis speed reducer.

As a preferred embodiment, the both sides of mount pad all are provided with a axle bearing assembly, the inner wall fixedly connected with cutting motor mounting panel of a axle bearing assembly, the externally mounted of mount pad, cutting motor mounting panel has the hydro-cylinder seat, first optical axis is installed to one side of hydro-cylinder seat, the chamfer hydro-cylinder is installed to one side of first optical axis, the cutting motor is installed to one side of cutting motor mounting panel, the outer wall fixedly connected with installation saw bit of cutting motor output, the inner wall difference fixedly connected with of mount pad hits the piece and hits the piece with.

As a preferred embodiment, cylinder supports are installed on two sides of the installation base, a cylinder and a linear bearing are installed on the outer wall of each cylinder support, a sucker is fixedly connected to one end of a cylinder rod of each cylinder, and a second optical axis is installed on the outer wall of each sucker.

As a preferred embodiment, a hinge seat is installed on one side of the bed body, a turnover table is installed on the other side of the bed body, shaft ends of the bed body and the turnover table are respectively fixed with lug rings at two ends of a turnover oil cylinder to be connected, a baffle is installed on the outer wall of the turnover table through bolts, a camera is installed on one side of the X-axis sliding plate assembly, and a cantilever operation box is installed on the outer wall of the bed body.

Compared with the prior art, the utility model discloses an advantage lies in with positive effect:

the utility model discloses in, the utility model provides a four-axis bridge cutting machine, can realize the horizontal rip cutting of panel and expect, the polygon cutting, the circular arc cutting, 45 chamfer functions are provided, expand the A axle on four-axis bridge cutting machine basis, can be at 0 °, 45 two position dead axle processing, can be to panel rip cutting, the chamfer, a grab board shift mechanism is provided, carry out panel aversion to cutting path interference position in the cutting process, avoid extravagant, improve the panel rate of utilization, provide supplementary feed mechanism, the mesa becomes about 85 ~ 87 of horizontal angle during the material loading, avoid the cracked problem of big board material loading, an intelligent vision operating system is provided, intelligent vision system snatchs the panel size, whether there is the defect in the analysis, intelligent typesetting, panel automatic shift avoids interfering, the very big improvement of more traditional device operation quality and availability factor.

Drawings

Fig. 1 is a perspective view of the present invention;

fig. 2 is a front view of the present invention;

FIG. 3 is an enlarged view of the present invention at IV;

FIG. 4 is an enlarged view of the position I and the position II of the present invention;

fig. 5 isbase:Sub>A cross-sectional view taken along linebase:Sub>A-base:Sub>A of the present invention;

FIG. 6 is an enlarged view of the point III of the present invention;

fig. 7 is a top view of the present invention.

Illustration of the drawings: 1. a bed body; 2. overturning the table top; 3. a camera; 4. a baffle plate; 5. a cross beam; 6. a cantilever operation box; 7. turning over the oil cylinder; 8. a winch shaft seat; 9. a drive assembly; 10. a coupling; 11. a ball screw assembly; 12. a skateboard assembly; 13. an X-axis slide assembly; 14. a rack; 15. a gear; 16. an X-direction guide rail; 17. a first slider; 18. chamfering the oil cylinder; 19. a first optical axis; 20. a cylinder block; 21. a C-axis motor; 22. a C-axis reducer; 23. a mounting seat; 24. a cylinder; 25. a shaft bearing assembly; 26. a second optical axis; 27. a linear bearing; 28. a suction cup; 29. a cylinder support; 30. cutting the motor; 31. cutting the motor mounting plate; 32. a Y-direction guide rail; 33. a second slider; 34. a Z-direction guide rail; 35. a collision block of 0 degree; 36. a bump block of 45 degrees; 37. a saw blade.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without making creative efforts belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

The invention will be further described with reference to the accompanying drawings and specific embodiments

Example 1

As shown in fig. 1-4, the utility model provides a technical solution: a visual bridge cutting machine comprises a machine body 1, wherein a Y-direction guide rail 32 and a rack 14 are mounted at the top of the machine body 1. The top of the Y-direction guide rail 32 is provided with a second sliding block 33, the top of the second sliding block 33 is provided with a cross beam 5, the top of the cross beam 5 is provided with a driving assembly 9, an output shaft of the driving assembly 9 is provided with a gear 15, the top and the outer side of the cross beam 5 are both provided with an X-direction guide rail 16, the top of the cross beam 5 is provided with a rack 14, the gear 15 is meshed with the rack 14, and the top of the X-direction guide rail 16 is provided with a first sliding block 17.

In this embodiment, the driving assembly 9 drives the gear 15 to rotate through the motor to engage with the rack 14, so as to reciprocate the cross beam 5 along the direction of the Y-direction guide rail 32, and the driving assembly 9 drives the gear 15 to rotate through the motor to engage with the rack 14, so as to reciprocate the X-axis slider assembly 13 along the direction of the X-direction guide rail 16.

Example 2

As shown in fig. 1-4, the driving assembly 9 is composed of a servo motor and a speed reducer; an X-axis sliding plate assembly 13 is arranged at the top of the lathe bed 1, and the X-axis sliding plate assembly 13 is connected with a driving assembly 9; an X-axis sliding plate assembly 13 is connected with a first sliding block 17, a ball screw assembly 11 is arranged on one side of the X-axis sliding plate assembly 13, a nut of the ball screw assembly 11 is fixedly connected with the X-axis sliding plate assembly 13, a Z-direction sliding plate assembly 12 is arranged on the top of the machine body 1, a Z-direction guide rail 34 is arranged on the top of the Z-direction sliding plate assembly 12, and a screw of the ball screw assembly 11 is fixedly connected with the Z-direction sliding plate assembly 12; the top end of the X-axis sliding plate assembly 13 is connected with the driving assembly 9, and an output shaft of the driving assembly 9 is connected with the shaft end of the ball screw assembly 11 through a coupling 10; the outer wall of the Z-direction sliding plate assembly 12 is provided with a C-axis speed reducer 22, the input end of the C-axis speed reducer 22 is provided with a C-axis motor 21, and the output end of the C-axis speed reducer 22 is provided with a mounting seat 23; the two sides of the mounting seat 23 are respectively provided with an A-axis bearing assembly 25, the inner wall of the A-axis bearing assembly 25 is fixedly connected with a cutting motor mounting plate 31, the outsides of the mounting seat 23 and the cutting motor mounting plate 31 are provided with an oil cylinder seat 20, one side of the oil cylinder seat 20 is provided with a first optical axis 19, one side of the first optical axis 19 is provided with a chamfering oil cylinder 18, one side of the cutting motor mounting plate 31 is provided with a cutting motor 30, the outer wall of the output end of the cutting motor 30 is fixedly connected with a mounting saw blade 37, and the inner wall of the mounting seat 23 is respectively and fixedly connected with a 0-degree collision block 35 and a 45-degree collision block 36; both sides of the mounting seat 23 are provided with cylinder brackets 29, the outer wall of each cylinder bracket 29 is provided with a cylinder 24 and a linear bearing 27, one end of a cylinder rod of each cylinder 24 is fixedly connected with a sucker 28, and the outer wall of each sucker 28 is provided with a second optical axis 26; a hinge seat 8 is installed on one side of the bed body 1, a turnover table top 2 is installed on the other side of the bed body 1, shaft ends of the bed body 1 and the turnover table top 2 are respectively fixed with lug rings at two ends of a turnover oil cylinder 7 to be connected, a baffle 4 is installed on the outer wall of the turnover table top 2 through bolts, a camera 3 is installed on one side of an X-axis sliding plate assembly 13, and a cantilever operation box 6 is installed on the outer wall of the bed body 1.

In this embodiment, a nut of the ball screw assembly 11 and a screw of the ball screw assembly 11 form a transmission pair, a motor of the drive assembly 9 drives the coupling 10 and the ball screw assembly 11 to rotate, so that the Z-direction slide plate assembly 12 reciprocates along the Z-direction guide rail 34, a C-axis motor 21 drives a C-axis speed reducer 22 to rotate, so that the mounting base 23 rotates within a range of 0 to 361 ° along the center of the C-axis speed reducer 22, the cutting motor mounting plate 31 flexibly rotates along the center of the a-axis bearing assembly 25 and stops when hitting against a 0 ° hitting block 35 and a 45 ° hitting block 36 respectively, an optical axis 26 is mounted on the suction cup 28, the optical axis 26 penetrates through the linear bearing 27 to form a guide pair, the suction cup 28 is connected with a negative pressure air source through an air pipe, the optical axis 26 is mounted on the suction cup 28, the optical axis 26 penetrates through the linear bearing 27 to form a guide pair, and the suction cup 28 is connected with the negative pressure air source through an air pipe.

The working principle is as follows:

as shown in fig. 1-4, the driving assembly 9 drives the gear 15 to rotate through the motor, and is engaged with the rack 14, so that the beam 5 reciprocates along the direction of the Y-direction guide rail 32, the driving assembly 9 drives the gear 15 to rotate through the motor, and is engaged with the rack 14, so that the X-axis sliding plate assembly 13 reciprocates along the direction of the X-direction guide rail 16, the nut of the ball screw assembly 11 and the screw of the ball screw assembly 11 form a transmission pair, the motor of the driving assembly 9 drives the coupler 10 and the ball screw assembly 11 to rotate, so that the Z-direction sliding plate assembly 12 reciprocates along the Z-direction guide rail 34, the C-axis motor 21 drives the C-axis reducer 22 to rotate, so that the mounting base 23 rotates along the center of the C-axis reducer 22 within the range of 0 ° to 361 °, the cutting motor mounting plate 31 flexibly rotates along the center of the a-axis bearing assembly 25, and stops when hitting against the 0 ° hitting block 35 and the 45 ° hitting block 36, the optical axis 26 and the optical axis 26 mounted on the suction cup 28 passes through the linear bearing 27 to form a guide pair, the suction cup 28, and the suction cup 28 is connected with the negative pressure source through the air pipe, thereby improving the working efficiency of the suction cup.

Finally, it should be noted that: the above-mentioned embodiments are only used for illustrating the technical solution of the present invention, and not for limiting the same; although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (9)

1. The utility model provides a visual bridge cutting machine, includes lathe bed (1), its characterized in that: y guide rail (32) and rack (14) are installed to the top of lathe bed (1), second slider (33) is installed to the top of Y guide rail (32), crossbeam (5) are installed at the top of second slider (33), drive assembly (9) are installed at the top of crossbeam (5), gear (15) are installed to the output shaft of drive assembly (9), X is all installed to the top and the outside of crossbeam (5) to guide rail (16), rack (14) are installed at the top of crossbeam (5), gear (15) are connected with rack (14) meshing, X is provided with first slider (17) to the top of guide rail (16).

2. The visual bridge cutting machine of claim 1, wherein: the driving assembly (9) is formed by combining a servo motor and a speed reducer.

3. The visual bridge cutting machine according to claim 1, wherein: an X-axis sliding plate assembly (13) is installed at the top of the lathe bed (1), and the X-axis sliding plate assembly (13) is connected with a driving assembly (9).

4. The visual bridge cutting machine of claim 3, wherein: x axle slide assembly (13) is connected with first slider (17), one side of X axle slide assembly (13) is provided with ball screw assembly (11), the screw and X axle slide assembly (13) fixed connection of ball screw assembly (11), Z is installed to the top of lathe bed (1) to slide assembly (12), and Z is provided with Z to guide rail (34) to the top of slide assembly (12) the lead screw and the Z of ball screw assembly (11) are to slide assembly (12) fixed connection.

5. The visual bridge cutting machine of claim 3, wherein: the top end of the X-axis sliding plate assembly (13) is connected with the driving assembly (9), and an output shaft of the driving assembly (9) is connected with the shaft end of the ball screw assembly (11) through a shaft coupling (10).

6. The visual bridge cutting machine according to claim 4, wherein: the Z is to the outer wall of slide assembly (12) and installs C axle speed reducer (22), C axle motor (21) is installed to the input of C axle speed reducer (22), mount pad (23) are installed to the output of C axle speed reducer (22).

7. The visual bridge cutting machine of claim 6, wherein: the both sides of mount pad (23) all are provided with A axle bearing assembly (25), inner wall fixedly connected with cutting motor mounting panel (31) of A axle bearing assembly (25), the externally mounted of mount pad (23), cutting motor mounting panel (31) has hydro-cylinder seat (20), first optical axis (19) are installed to one side of hydro-cylinder seat (20), chamfer hydro-cylinder (18) are installed to one side of first optical axis (19), cutting motor (30) are installed to one side of cutting motor mounting panel (31), the outer wall fixedly connected with installation saw bit (37) of cutting motor (30) output, the inner wall of mount pad (23) is fixedly connected with 0 respectively and hits piece (35) and 45 hits piece (36).

8. The visual bridge cutting machine of claim 6, wherein: cylinder support (29) are all installed to the both sides of mount pad (23), outer wall installation cylinder (24), linear bearing (27) of cylinder support (29), the one end fixedly connected with sucking disc (28) of cylinder (24) jar pole, second optical axis (26) are installed to the outer wall of sucking disc (28).

9. The visual bridge cutting machine according to claim 3, wherein: the automatic turning machine is characterized in that a hinge seat (8) is installed on one side of the machine body (1), a turning table board (2) is installed on the other side of the machine body (1), shaft ends of the machine body (1) and the turning table board (2) are respectively fixed with lug rings at two ends of a turning oil cylinder (7) to be connected, a baffle (4) is installed on the outer wall of the turning table board (2) through bolts, a camera (3) is installed on one side of an X-axis sliding plate assembly (13), and a cantilever operation box (6) is installed on the outer wall of the machine body (1).

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