CN219189021U - Laser cutting machine with automatic positioning function - Google Patents

Abstract

The utility model provides a laser cutting machine with an automatic positioning function, which belongs to the technical field of industrial processing and aims to solve the problems that the existing laser cutting machine cuts smaller waste materials, the waste materials are easy to fall into the cutting machine and a worker is required to manually take out the waste materials, and the laser cutting machine comprises a cutting main body, a cutting protective cover, a cutting sliding arm, a laser cutting head, a cutting computer, a waste material cleaning mechanism and a waste material falling mechanism; the cutting protection cover is connected to the rear end face of the cutting main body in a plug-in manner; the cutting sliding arm is connected to the upper end face of the cutting main body in a sliding manner; the laser cutting head is connected to the cutting slide arm in a sliding manner; the cutting computer is fixedly connected to the rear end face of the cutting sliding arm; the waste cleaning mechanism is arranged inside the cutting main body; the waste drop mechanism is disposed inside the cutting body. Adopt waste material clearance mechanism, realize the inside waste material of the clean cutting main part of staff of being convenient for, adopt the waste material to drop the mechanism, realize improving the efficiency of the inside waste material of staff clearance cutting machine.

Description

Laser cutting machine with automatic positioning function

Technical Field

The utility model belongs to the technical field of industrial processing, and particularly relates to a laser cutting machine with an automatic positioning function.

Background

The laser cutting machine is used for generating laser from the laser, irradiating the laser on the material to cut the material, and when a worker places the material on the cutting plate, setting the shape and the size of the material, controlling the laser to automatically position and cut the material.

According to CN201911417994.6, the utility model discloses a laser cutting machine, which belongs to the field of laser cutting equipment, and comprises a frame, wherein a supporting platform is fixedly arranged at the top of the frame, the supporting platform comprises a plurality of supporting plates uniformly and fixedly arranged along the length direction of the frame, and a cleaning mechanism for cleaning waste materials on the supporting plates is arranged at the top of the frame; the cleaning mechanism comprises a screw rod which is horizontally and slidingly connected to the top of the frame, the axial direction of the screw rod is parallel to the extending direction of the supporting plate, and the end part of the screw rod is connected with a driving assembly which drives the screw rod to horizontally slide along the top of the frame; the top of the screw rod is horizontally connected with a fixing seat in a sliding manner along the axial direction of the screw rod, one end of the screw rod is fixedly connected with a driving motor for driving the screw rod to rotate, the top of the fixing seat is fixedly provided with a hydraulic cylinder, a cylinder body of the hydraulic cylinder is fixedly connected with the top of the fixing seat, a piston rod of the hydraulic cylinder extends to the bottom of the fixing seat and is fixedly connected with a fixing plate, and a shot blasting device is fixedly arranged at the bottom of the fixing plate.

Based on the above, current laser cutting machine's cutting board is hollow out construction, can cut out less waste material when laser cutting machine cuts the material, and the waste material is difficult to support on the cutting board, and the waste material falls into laser cutting machine inside easily, needs the staff to manually take out the inside waste material of laser cutting machine, and the staff clearance laser cutting machine inside waste material is comparatively loaded down with trivial details.

Disclosure of Invention

In order to solve the technical problems, the utility model provides a laser cutting machine with an automatic positioning function, so as to solve the problems that a cutting plate of the existing laser cutting machine is of a hollow structure, small waste is cut when the laser cutting machine cuts materials, the waste is difficult to support on the cutting plate, the waste is easy to fall into the laser cutting machine, a worker is required to manually take out the waste in the laser cutting machine, and the worker is complicated to clean the waste in the laser cutting machine.

The utility model discloses a purpose and an effect of a laser cutting machine with an automatic positioning function, which are achieved by the following specific technical means:

a laser cutting machine with an automatic positioning function comprises a cutting main body, a cutting protective cover, a cutting sliding arm, a laser cutting head, a cutting computer, a waste storage box, a waste cleaning mechanism and a waste falling mechanism; the cutting protection cover is connected to the rear end face of the cutting main body in a plug-in manner; the cutting sliding arm is connected to the upper end face of the cutting main body in a sliding manner; the laser cutting head is connected to the cutting slide arm in a sliding manner; the cutting computer is fixedly connected to the rear end face of the cutting sliding arm; the waste storage box is connected to the lower side of the inner part of the cutting main body in a sliding way; the waste cleaning mechanism is arranged inside the cutting main body; the waste drop mechanism is disposed inside the cutting body.

Further, waste material clearance mechanism is including: the device comprises a discharging motor, a discharging screw and a waste roller; the discharging motor is fixedly connected to the left side of the rear end face of the cutting main body; the discharging screw is coaxially and fixedly connected to the rotating shaft of the discharging motor, is rotationally connected to the left side inside the cutting main body and is in threaded connection with the waste storage box; the waste material gyro wheel fixed connection is at waste material case right-hand member face rear side, and the waste material gyro wheel slides in the inside right side of cutting main part.

Further, waste material mechanism that drops including: a reciprocating rack and a reciprocating gear; the reciprocating rack is fixedly connected to the left side of the upper end face of the waste storage box; the reciprocating gear is rotatably connected to the right side inside the cutting main body, and the reciprocating rack and the reciprocating gear are meshed to form a gear-rack transmission mechanism.

Further, the waste dropping mechanism further comprises: a bevel gear A and a bevel gear B are placed; the bevel gear A is coaxially and fixedly connected to the right side of the reciprocating gear; the bevel gear B is rotatably connected to the left side inside the cutting main body, and the bevel gear A and the bevel gear B are meshed to form a bevel gear transmission mechanism.

Further, the waste dropping mechanism further comprises: a half gear, a full gear and a rack are placed; the placing half gear is coaxially and fixedly connected to the placing bevel gear B; the placing all-gear is rotatably connected to the left side inside the cutting main body, and the placing half-gear and the placing all-gear are meshed to form a gear transmission mechanism; the placing rack is connected to the left side inside the cutting main body in a sliding mode, the placing rack and the placing half gear are meshed to form a gear-rack transmission mechanism together, and the placing rack and the placing all-gear are meshed to form the gear-rack transmission mechanism together.

Further, the waste dropping mechanism further comprises: cutting the placing plate and the placing pulley; the cutting placing plate is connected inside the cutting main body in a sliding manner and is fixedly connected with the placing rack; the four groups of placing pulleys are respectively fixedly connected to four corners of the cutting placing plate, and the four groups of placing pulleys respectively slide inside the cutting main body.

Compared with the prior art, the utility model has the following beneficial effects:

according to the utility model, by adopting the waste cleaning mechanism, the cut materials are placed on the cutting placing plate, the laser cutting head cuts the materials, the cut waste falls into the waste storage box, the discharging motor drives the waste storage box to slide, a worker conveniently cleans the waste falling into the waste storage box, the problem that the worker is required to draw out from the cutting main body when the waste cut from the materials falls into the cutting main body is avoided, and the worker is convenient to clean the waste in the cutting main body.

According to the utility model, by adopting the waste falling mechanism, the cutting placing plate is driven to slide back and forth to vibrate when the waste storage box slides out, the waste attached to the cutting placing plate is vibrated into the waste storage box, the step of cleaning the waste on the cutting placing plate is reduced when the waste is cleaned, and the efficiency of cleaning the waste in the cutting machine by staff is improved.

Drawings

Fig. 1 is a schematic diagram of the front view of the laser cutting machine of the present utility model.

Fig. 2 is a schematic rear view of the laser cutting machine of the present utility model.

Fig. 3 is a schematic view of the internal transmission structure of the laser cutting machine of the present utility model.

FIG. 4 is a schematic view of the waste cleaning mechanism of the present utility model.

Fig. 5 is a schematic view showing the structure of the cutting placement plate according to the present utility model in a lower view.

Fig. 6 is a schematic rear view of the waste dropping mechanism of the present utility model.

Fig. 7 is a schematic diagram of the structure of the waste dropping mechanism of the present utility model in front view.

In the figure, the correspondence between the component names and the drawing numbers is:

1. cutting the main body; 2. cutting the protective cover; 3. cutting a slide arm; 4. a laser cutting head; 5. cutting a computer; 6. a discharging motor; 601. a discharge screw; 7. a waste bin; 701. a waste roller; 702. a reciprocating rack; 8. a shuttle gear; 801. placing a bevel gear A; 9. placing a half gear; 901. placing a bevel gear B; 10. placing all gears; 11. cutting the placing plate; 1101. placing a rack; 1102. and (5) placing a pulley.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples.

Examples:

as shown in fig. 1 to 7:

the utility model provides a laser cutting machine with an automatic positioning function, which comprises a cutting main body 1, a cutting protective cover 2, a cutting sliding arm 3, a laser cutting head 4, a cutting computer 5, a waste storage box 7, a waste cleaning mechanism and a waste dropping mechanism, wherein the cutting main body is provided with a cutting head; the cutting protection cover 2 is connected to the rear end face of the cutting main body 1 in a plug-in manner; the cutting slide arm 3 is connected to the upper end face of the cutting main body 1 in a sliding way; the laser cutting head 4 is connected to the cutting slide arm 3 in a sliding manner; the cutting computer 5 is fixedly connected to the rear end face of the cutting slide arm 3; the waste storage box 7 is connected to the lower side of the inner part of the cutting main body 1 in a sliding way; the waste cleaning mechanism is arranged inside the cutting main body 1; the waste dropping mechanism is provided inside the cutting body 1.

Wherein, waste material clearance mechanism is including: a discharge motor 6, a discharge screw 601 and a waste roller 701; the discharging motor 6 is fixedly connected to the left side of the rear end face of the cutting main body 1; the discharge screw 601 is coaxially and fixedly connected to the rotating shaft of the discharge motor 6, the discharge screw 601 is rotatably connected to the left side inside the cutting main body 1, and the discharge screw 601 is in threaded connection with the waste storage box 7; the waste material gyro wheel 701 fixed connection is at the waste material case 7 right-hand member face rear side, and waste material gyro wheel 701 slides in the inside right side of cutting main part 1, and in the use, the rotation of ejection of compact motor 6 pivot drives ejection of compact lead screw 601 and rotates, and ejection of compact lead screw 601 rotates and drives waste material case 7 and slide, and waste material case 7 opening width is greater than the width of cutting main part 1 cutting area, and waste material case 7 slides and drives waste material gyro wheel 701 and slide.

Wherein, waste material mechanism that drops is including: a reciprocating rack 702 and a reciprocating gear 8; the round-trip rack 702 is fixedly connected to the left side of the upper end surface of the waste bin 7; the round-trip gear 8 is rotatably connected to the right side inside the cutting main body 1, the round-trip rack 702 and the round-trip gear 8 are meshed to form a gear-rack transmission mechanism, and in the use process, the waste storage box 7 slides to drive the round-trip rack 702 to slide, and the round-trip rack 702 slides to drive the meshed round-trip gear 8 to rotate.

Wherein, waste material mechanism that drops still includes: bevel gear A801 and bevel gear B901; the bevel gear A801 is coaxially and fixedly connected to the right side of the reciprocating gear 8; the bevel gear B901 is rotationally connected to the left side inside the cutting main body 1, the bevel gear A801 and the bevel gear B901 are meshed to form a bevel gear transmission mechanism, and in the use process, the round-trip gear 8 rotates to drive the bevel gear A801 to rotate, and the bevel gear A801 rotates to drive the meshed bevel gear B901 to rotate.

Wherein, waste material mechanism that drops still includes: a half gear 9, a full gear 10 and a rack 1101; the placing half gear 9 is coaxially and fixedly connected to the placing bevel gear B901; the placing all-gear 10 is rotationally connected to the left side inside the cutting main body 1, and the placing half-gear 9 and the placing all-gear 10 are meshed to form a gear transmission mechanism together; placing rack 1101 sliding connection is in the inside left side of cutting main part 1, placing rack 1101 and placing half gear 9 meshing constitute rack and pinion drive jointly, placing rack 1101 and placing full gear 10 meshing constitute rack and pinion drive jointly, in the use, placing bevel gear B901 rotates and drives to place half gear 9 rotation, place half gear 9 and when placing full gear 10 meshing, place half gear 9 and do not mesh with placing rack 1101, place half gear 9 and drive to place full gear 10 rotation, place full gear 10 rotation and drive to place rack 1101 and slide right, place half gear 9 and place rack 1101 meshing time, place half gear 9 and place full gear 10 and break away from the meshing state, place half gear 9 drives to place rack 1101 and slides left.

Wherein, waste material mechanism that drops still includes: cutting the placement plate 11 and the placement pulley 1102; the cutting placing plate 11 is slidably connected inside the cutting main body 1, and the cutting placing plate 11 is fixedly connected with the placing rack 1101; the placing pulleys 1102 are provided with four groups in total, the four groups of placing pulleys 1102 are respectively and fixedly connected with four corners of the cutting placing plate 11, the four groups of placing pulleys 1102 respectively slide inside the cutting main body 1, in the using process, the placing racks 1101 slide to drive the cutting placing plate 11 to slide, and the cutting placing plate 11 slide to drive the placing pulleys 1102 to slide.

Specific use and action of the embodiment:

in the use, the rotation of ejection of compact motor 6 pivot drives ejection of compact lead screw 601 and rotates, ejection of compact lead screw 601 rotates and drives waste deposit box 7 and slide, waste deposit box 7 opening width is greater than the width of cutting main part 1 cutting area, waste deposit box 7 slides and drives waste gyro wheel 701 and slide, waste deposit box 7 slides and drives back and forth rack 702 and slide, back and forth rack 702 slides and drives the back and forth gear 8 rotation of meshing, back and forth gear 8 rotates and drives and place bevel gear A801 and rotate, place bevel gear A801 rotates and drives the bevel gear B901 of meshing and rotates, place bevel gear B901 rotates and drives and place half gear 9 and rotate, place half gear 9 and place full gear 10 and rotate, place full gear 10 and rotate and drive and place rack 1101 and slide to the right, place half gear 9 and place rack 1101 and slide, place half gear 9 and place full gear 10 and break away from the engagement state, place half gear 9 and drive and place rack 1101 and slide and place board 11, place board 11 and slide and drive and place pulley 1102 and place and slide, when realizing that waste deposit box 7 slides out and drive and place board 11 and shake.

Claims (6)

1. A laser cutting machine with automatic positioning function is characterized in that: the cutting machine comprises a cutting main body (1), a cutting protective cover (2), a cutting sliding arm (3), a laser cutting head (4), a cutting computer (5), a waste storage box (7), a waste cleaning mechanism and a waste falling mechanism; the cutting protection cover (2) is connected to the rear end face of the cutting main body (1) in a plug-in manner; the cutting slide arm (3) is connected to the upper end face of the cutting main body (1) in a sliding manner; the laser cutting head (4) is connected to the cutting slide arm (3) in a sliding manner; the cutting computer (5) is fixedly connected to the rear end face of the cutting sliding arm (3); the waste storage box (7) is connected to the lower side of the inside of the cutting main body (1) in a sliding way; the waste cleaning mechanism is arranged inside the cutting main body (1); the waste falling mechanism is arranged inside the cutting main body (1).

2. A laser cutting machine with automatic positioning function as set forth in claim 1, wherein: the waste material clearance mechanism is including: a discharging motor (6), a discharging screw (601) and a waste roller (701); the discharging motor (6) is fixedly connected to the left side of the rear end face of the cutting main body (1); the discharging screw (601) is coaxially and fixedly connected to the rotating shaft of the discharging motor (6), the discharging screw (601) is rotatably connected to the left side inside the cutting main body (1), and the discharging screw (601) is in threaded connection with the waste storage box (7); the waste roller (701) is fixedly connected to the rear side of the right end face of the waste storage box (7), and the waste roller (701) slides to the right side inside the cutting main body (1).

3. A laser cutting machine with automatic positioning function as set forth in claim 1, wherein: the waste material mechanism that drops is including: a reciprocating rack (702) and a reciprocating gear (8); the reciprocating rack (702) is fixedly connected to the left side of the upper end face of the waste storage box (7); the reciprocating gear (8) is rotatably connected to the right side inside the cutting main body (1), and the reciprocating rack (702) and the reciprocating gear (8) are meshed to form a gear-rack transmission mechanism.

4. A laser cutting machine with automatic positioning function as claimed in claim 3, wherein: the waste material mechanism that drops still includes: a bevel gear A (801) and a bevel gear B (901) are placed; the bevel gear A (801) is coaxially and fixedly connected to the right side of the reciprocating gear (8); the bevel gear B (901) is rotatably connected to the left side inside the cutting main body (1), and the bevel gear A (801) and the bevel gear B (901) are meshed to form a bevel gear transmission mechanism.

5. The laser cutting machine with automatic positioning function according to claim 4, wherein: the waste material mechanism that drops still includes: a half gear (9), a full gear (10) and a rack (1101); the placing half gear (9) is coaxially and fixedly connected to the placing bevel gear B (901); the placing all-gear (10) is rotationally connected to the left side inside the cutting main body (1), and the placing half-gear (9) and the placing all-gear (10) are meshed to form a gear transmission mechanism together; the rack (1101) is slidably connected to the left side inside the cutting main body (1), the rack (1101) and the half gear (9) are meshed to form a gear-rack transmission mechanism, and the rack (1101) and the full gear (10) are meshed to form the gear-rack transmission mechanism.

6. The laser cutting machine with automatic positioning function according to claim 5, wherein: the waste material mechanism that drops still includes: cutting the placement plate (11) and the placement pulley (1102); the cutting placing plate (11) is connected inside the cutting main body (1) in a sliding mode, and the cutting placing plate (11) is fixedly connected with the placing rack (1101); the four groups of placing pulleys (1102) are arranged in total, the four groups of placing pulleys (1102) are respectively and fixedly connected to four corners of the cutting placing plate (11), and the four groups of placing pulleys (1102) respectively slide inside the cutting main body (1).

Images