CN220547786U

CN220547786U - 3D processing laser lathe

Info

Publication number: CN220547786U
Application number: CN202321837276.6U
Authority: CN
Inventors: 李鹤; 王绍存; 孙玉峰; 陈恒超; 李长吉; 毕玉强; 王健
Original assignee: Shandong Huasong Beili Intelligent Technology Co ltd; Jinan vocational college
Current assignee: Shandong Huasong Beili Intelligent Technology Co ltd; Jinan vocational college
Priority date: 2023-07-13
Filing date: 2023-07-13
Publication date: 2024-03-01
Anticipated expiration: 2033-07-13

Abstract

The utility model belongs to the technical field of laser cutting machines, in particular to a 3D processing laser lathe, which comprises a frame, wherein a conveyor belt is rotatably connected above the inside of the frame; the upper surface of the frame is fixedly connected with a supporting frame; limit grooves which are symmetrically arranged are formed above the support frame; a connecting plate is connected in the limiting groove in a sliding way; the connecting plate is provided with a moving assembly; through the third motor, the third motor drives the second rotating rod to rotate, the second rotating rod simultaneously rotates to drive the second arc gear to rotate, and the second arc gear is meshed with the second plane gear intermittently, and the second arc gear is meshed with the second plane gear alternately, so that when the second arc gear rotates, the connecting rod can reciprocate in a certain angle by taking the second plane gear as the center of a circle, an arc line can be formed in the rotating process, a curve can be formed under the cooperation of the conveying belt, curve processing can be performed on a product, and the application range can be increased.

Description

3D processing laser lathe

Technical Field

The utility model belongs to the technical field of laser cutting machines, and particularly relates to a 3D processing laser lathe.

Background

The laser lathe is a device for processing a product by using a high-energy laser beam, and can cut, surface treat, punch and the like the product.

At present, the specific mode of cutting products by the existing laser lathe is as follows: through placing the product on the processing board, the processing board can realize reciprocating motion under the cooperation of chain, and laser cutting machine on the laser lathe can carry out the random movement under the cooperation of lead screw, through the cooperation of lead screw and chain, can carry out accurate cutting to the product.

In the prior art, although the product can be precisely cut through the cooperation of the screw rod and the chain, when the laser cutting machine cuts the product, the product can only be processed in a straight line, the curve processing can not be carried out on the product, and the application range is lower.

Therefore, a 3D processing laser lathe is proposed for the above-mentioned problems.

Disclosure of Invention

In order to overcome the defects in the prior art and solve the problems, the 3D processing laser lathe is provided.

The technical scheme adopted for solving the technical problems is as follows: the utility model relates to a 3D processing laser lathe, which comprises a frame, wherein a conveyor belt is rotationally connected above the inside of the frame; the upper surface of the frame is fixedly connected with a supporting frame; limit grooves which are symmetrically arranged are formed above the support frame; a connecting plate is connected in the limiting groove in a sliding way; the connecting plate is provided with a moving assembly, the moving assembly comprises a screw rod and a connecting frame, and the connecting frame is connected to the outer side of the screw rod in a sliding manner; an adjusting assembly is arranged in the connecting frame and comprises a second plane gear and an arc gear, and the second plane gear is meshed with the arc gear intermittently; a rotating rod III is fixedly connected to the middle part of the second plane gear; a connecting rod is fixedly connected above the rotating rod three; a laser cutting machine is fixedly connected below the three ends of the connecting rod, which are far away from the rotating rod; the support frame is provided with a lifting component, and the lifting component is used for lifting the connecting plate.

Preferably, the moving assembly comprises a first motor, and the first motor is fixedly connected above one side, away from the conveyor belt, of one of the connecting plates; the output end of the motor is rotationally connected with a screw rod, the screw rod penetrates through one of the connecting plates, and the screw rod is rotationally connected in the connecting plate; the outer side of the screw rod is connected with a connecting frame in a sliding manner; the fixing rods are fixedly connected above the two connecting plates at positions corresponding to the connecting frames, and the connecting frames are connected to the outer sides of the fixing rods in a sliding mode.

Preferably, the adjusting component comprises a mounting box, and the mounting box is fixedly connected above the inside of the connecting frame; a motor III is fixedly connected below the inner part of the mounting box; the third output end of the motor is rotationally connected with a second rotating shaft; the outer side of the rotating shaft is fixedly connected with a bevel gear III which is symmetrically arranged; the outer side of the bevel gear III is meshed with a bevel gear IV; a second rotating rod is fixedly connected to the middle part of the bevel gear IV, the upper part of the second rotating rod penetrates through the connecting frame, and the second rotating rod is rotationally connected to the bottom of the mounting box; an arc gear is fixedly connected above the second rotating rod; the connecting frame is rotatably connected with a rotating rod III at the position corresponding to the arc gear; the second plane gear is fixedly connected to the outer side of the rotating rod corresponding to the arc gear, and is meshed with the arc gear intermittently, and the second plane gear is meshed with the two arc gears alternately.

Preferably, the lifting assembly comprises a second motor, and the second motor is fixedly connected to the middle part above the support frame; the output end of the motor II is rotationally connected with a rotating shaft I; the outer side of the first rotating shaft is fixedly connected with a first bevel gear which is symmetrically arranged; the outer side of the bevel gear I is meshed with a bevel gear II; a rotating rod I is fixedly connected to one side, away from the bevel gear I, of the bevel gear II; a plane gear I is fixedly connected to one side, far away from the bevel gear II, of the rotating rod I; the position of the connecting plate corresponding to the first plane gear is fixedly connected with a rack, and the first plane gear is meshed with the rack.

Preferably, the support frame is fixedly connected with symmetrically arranged fixed blocks corresponding to the first rotating rod, and the rotating rod is rotatably connected in the fixed blocks.

Preferably, a fixing ring is fixedly connected below the third rotating rod and is positioned in the mounting box; the sleeve is fixedly connected to the position, corresponding to the fixing ring, in the mounting box, and the fixing ring is rotatably connected in the sleeve.

The utility model has the beneficial effects that:

the utility model provides a 3D processing laser lathe, which is characterized in that a motor III is started by a worker, the motor III drives a rotating shaft II to rotate, the rotating shaft II drives a bevel gear III to rotate, the bevel gear III drives a bevel gear IV to rotate, the bevel gear IV drives a rotating rod II to rotate, two rotating rods II simultaneously rotate and drive two arc gears to rotate, the arc gears are intermittently meshed with a plane gear II, and the two arc gears are alternately meshed with the plane gear II, so that when the two arc gears rotate, a connecting rod can reciprocate in a certain angle by taking the plane gear II as a circle center, an arc line can be formed in the rotating process, and a curve can be formed under the cooperation of a conveyor belt, thereby curve processing can be performed on a product, and the application range can be increased.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this application, illustrate embodiments of the utility model and together with the description serve to explain the utility model and do not constitute a limitation on the utility model. In the drawings:

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is a perspective view of the present utility model at the mobile assembly and the lift assembly;

FIG. 4 is a perspective view of a cross-sectional view of the mounting box of the present utility model;

fig. 5 is a perspective view of the present utility model at the adjustment assembly.

Legend description:

1. a frame; 11. a conveyor belt; 12. a support frame; 2. a first motor; 21. a screw rod; 22. a connecting frame; 23. a fixed rod; 3. a second motor; 31. a first rotating shaft; 32. bevel gears I; 33. bevel gears II; 34. rotating the first rod; 35. a first face gear; 36. a rack; 37. a connecting plate; 38. a limit groove; 4. a mounting box; 41. a third motor; 42. a second rotating shaft; 43. bevel gears III; 44. the bevel gear is dead; 45. a second rotating rod; 46. an arc gear; 47. a second plane gear; 48. rotating a rod III; 5. a connecting rod; 51. a laser cutting machine; 6. a sleeve; 7. and a fixed block.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Specific examples are given below.

Referring to fig. 1-5, the utility model provides a 3D processing laser lathe, which comprises a frame 1, wherein a conveyor belt 11 is rotatably connected above the inside of the frame 1; the upper surface of the frame 1 is fixedly connected with a supporting frame 12; symmetrically arranged limit grooves 38 are formed above the support frame 12; the limiting groove 38 is connected with a connecting plate 37 in a sliding way; the connecting plate 37 is provided with a moving assembly, the moving assembly comprises a screw rod 21 and a connecting frame 22, and the connecting frame 22 is connected to the outer side of the screw rod 21 in a sliding manner; an adjusting assembly is arranged in the connecting frame 22, and comprises a second plane gear 47 and an arc gear 46, wherein the second plane gear 47 is meshed with the arc gear 46 intermittently; a third rotating rod 48 is fixedly connected to the middle part of the second plane gear 47; a connecting rod 5 is fixedly connected above the third rotating rod 48; a laser cutting machine 51 is fixedly connected below one end, far away from the rotating rod III 48, of the connecting rod 5; the supporting frame 12 is provided with a lifting assembly, and the lifting assembly is used for lifting the connecting plate 37.

During operation, in the prior art, although the product can be precisely cut through the cooperation of the screw rod 21 and the chain, when the laser cutting machine 51 cuts the product, the product can only be processed in a straight line, and curve processing can not be performed on the product, so that the application range is low; the device conveys products on the conveyor belt 11 through staff, the staff starts the motor III 41, the motor III 41 drives the rotation shaft II 42 to rotate, the rotation shaft II 42 drives the bevel gear III 43 to rotate, the bevel gear III 43 rotates to drive the bevel gear IV to rotate, the bevel gear IV rotates to drive the rotation rod II 45 to rotate, the two rotation rods II 45 simultaneously rotate to drive the two arc gears 46 to rotate, the arc gears 46 are intermittently meshed with the two face gears 47, the two arc gears 46 are alternately meshed with the two face gears 47, and therefore when the two arc gears 46 rotate, the connecting rod 5 can rotate in a reciprocating manner in a certain angle by taking the two face gears 47 as the center of a circle, an arc is formed in the rotating process, and a curve can be formed under the cooperation of the conveyor belt 11, so that curve processing can be performed on the products, and the application range can be increased.

Further, as shown in fig. 1, 3 and 4, the moving assembly includes a motor one 2, and the motor one 2 is fixedly connected above one side of one of the connecting plates 37 away from the conveyor belt 11; the output end of the motor I2 is rotationally connected with a screw rod 21, the screw rod 21 penetrates through one of the connecting plates 37, and the screw rod 21 is rotationally connected in the connecting plate 37; the outer side of the screw rod 21 is connected with a connecting frame 22 in a sliding manner; a fixed rod 23 is fixedly connected above the two connecting plates 37 corresponding to the position of the connecting frame 22, and the connecting frame 22 is slidably connected to the outer side of the fixed rod 23.

During operation, the first motor 2 is started, the first motor 2 drives the screw rod 21 to rotate, the screw rod 21 rotates to drive the connecting frame 22 to slide outside the screw rod 21, and the connecting frame 22 slides to drive the laser cutting machine 51 to move, so that different positions can be machined.

Further, as shown in fig. 1, 3, 4 and 5, the adjusting assembly includes a mounting box 4, and the mounting box 4 is fixedly connected above the inside of the connecting frame 22; a motor III 41 is fixedly connected below the inner part of the mounting box 4; the output end of the third motor 41 is rotatably connected with a second rotating shaft 42; a bevel gear III 43 which is symmetrically arranged is fixedly connected to the outer side of the second rotating shaft 42; the outer side of the bevel gear III 43 is meshed with a bevel gear IV; a second rotating rod 45 is fixedly connected to the middle part of the bevel gear IV, the upper part of the second rotating rod 45 penetrates through the connecting frame 22, and the second rotating rod 45 is rotatably connected to the bottom of the mounting box 4; an arc gear 46 is fixedly connected above the second rotating rod 45; the third rotating rod 48 is rotatably connected to the connecting frame 22 at a position corresponding to the arc gear 46; the outer side of the third rotating rod 48 is fixedly connected with a second plane gear 47 corresponding to the position of the arc gear 46, the second plane gear 47 is meshed with the arc gear 46 intermittently, and the second plane gear 47 is meshed with the two arc gears 46 alternately.

During operation, the motor III 41 is started to drive the rotation shaft II 42 to rotate, the rotation shaft II 42 drives the bevel gear III 43 to rotate, the bevel gear III 43 rotates to drive the bevel gear IV to rotate, the bevel gear IV rotates to drive the rotation rod II 45 to rotate, the two rotation rods II 45 simultaneously rotate to drive the two arc gears 46 to rotate, the arc gears 46 are intermittently meshed with the plane gears II 47, the two arc gears 46 are alternately meshed with the plane gears II 47, and therefore when the two arc gears 46 rotate, the connecting rod 5 can rotate in a reciprocating manner in a certain angle by taking the plane gears II 47 as the circle center, an arc is formed in the rotating process, and a curve can be formed under the cooperation of the conveyor belt 11.

Further, as shown in fig. 2, 3 and 4, the lifting assembly includes a second motor 3, and the second motor 3 is fixedly connected to the middle part above the support frame 12; the output end of the second motor 3 is rotatably connected with a first rotating shaft 31; the outer side of the first rotating shaft 31 is fixedly connected with a first bevel gear 32 which is symmetrically arranged; a bevel gear II 33 is meshed with the outer side of the bevel gear I32; a first rotating rod 34 is fixedly connected to one side, away from the first bevel gear 32, of the second bevel gear 33; a face gear I35 is fixedly connected to one side, away from the bevel gear II 33, of the rotating rod I34; the connecting plate 37 is fixedly connected with a rack 36 at a position corresponding to the first face gear 35, and the first face gear 35 is meshed with the rack 36.

During operation, through start motor two 3, motor two 3 drive axis of rotation one 31 rotates, and axis of rotation one 31 rotates and drives bevel gear one 32 and rotate, and bevel gear one 32 rotates and drives dwang one 34 and rotate, and dwang one 34 rotates and drives face gear one 35 and rotate, and face gear one 35 rotates and drives rack 36 and go up and down, and rack 36 goes up and down to drive connecting plate 37 and goes up and down, and connecting plate 37 goes up and down to drive laser cutting machine 51 and goes up and down to can adjust the height of laser cutting machine 51, make the precision of cutting improve, reduce the error.

Further, as shown in fig. 2, 3 and 4, the support frame 12 is fixedly connected with symmetrically arranged fixed blocks 7 at positions corresponding to the first rotating rod 34, and the first rotating rod 34 is rotatably connected in the fixed blocks 7.

During operation, the first rotating rod 34 is rotationally connected in the first fixed block 7 through the fixed block 7 fixedly connected on the supporting frame 12, so that the position of the first rotating rod 34 can be limited, and the first rotating rod 34 is prevented from being deviated.

Further, as shown in fig. 4, a fixing ring is fixedly connected below the third rotating rod 48, and the fixing ring is located inside the mounting box 4; the sleeve 6 is fixedly connected to the position, corresponding to the fixing ring, in the mounting box 4, and the fixing ring is rotatably connected in the sleeve 6.

During operation, the fixing ring is rotationally connected in the sleeve 6 through the fixing ring fixedly connected below the third rotating rod 48 and the sleeve 6 fixedly connected in the mounting box 4, so that the position of the third rotating rod 48 can be limited.

Working principle:

in the prior art, although the product can be precisely cut through the cooperation of the screw rod 21 and the chain, when the laser cutting machine 51 cuts the product, the product can only be processed in a straight line, and curve processing can not be performed on the product, so that the application range is low; the device conveys products on the conveyor belt 11 through staff, the staff starts the motor III 41, the motor III 41 drives the rotation shaft II 42 to rotate, the rotation shaft II 42 drives the bevel gear III 43 to rotate, the bevel gear III 43 rotates to drive the bevel gear IV to rotate, the bevel gear IV rotates to drive the rotation rod II 45 to rotate, the two rotation rods II 45 simultaneously rotate to drive the two arc gears 46 to rotate, the arc gears 46 are intermittently meshed with the two face gears 47, the two arc gears 46 are alternately meshed with the two face gears 47, and therefore when the two arc gears 46 rotate, the connecting rod 5 can rotate in a reciprocating manner in a certain angle by taking the two face gears 47 as the center of a circle, an arc is formed in the rotating process, and a curve can be formed under the cooperation of the conveyor belt 11, so that curve processing can be performed on the products, and the application range can be increased.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims.

Claims

1. A 3D processing laser lathe, characterized in that: comprises a frame (1), wherein a conveyor belt (11) is rotatably connected above the inside of the frame (1); the upper surface of the frame (1) is fixedly connected with a supporting frame (12); limit grooves (38) which are symmetrically arranged are formed above the support frame (12); a connecting plate (37) is connected in a sliding way in the limiting groove (38); the connecting plate (37) is provided with a moving assembly, the moving assembly comprises a screw rod (21) and a connecting frame (22), and the connecting frame (22) is connected to the outer side of the screw rod (21) in a sliding manner; an adjusting assembly is arranged in the connecting frame (22), and comprises a second plane gear (47) and an arc gear (46), wherein the second plane gear (47) is meshed with the arc gear (46) intermittently; a rotating rod III (48) is fixedly connected to the middle part of the plane gear II (47); a connecting rod (5) is fixedly connected above the rotating rod III (48); a laser cutting machine (51) is fixedly connected below one end, far away from the rotating rod III (48), of the connecting rod (5); the lifting assembly is arranged on the supporting frame (12) and used for lifting the connecting plate (37).

2. The 3D machining laser lathe of claim 1, wherein: the moving assembly comprises a motor I (2), and the motor I (2) is fixedly connected above one side, far away from the conveyor belt (11), of one of the connecting plates (37); the output end of the motor I (2) is rotationally connected with a screw rod (21), the screw rod (21) penetrates through one of the connecting plates (37), and the screw rod (21) is rotationally connected in the connecting plate (37); the outer side of the screw rod (21) is connected with a connecting frame (22) in a sliding manner; a fixed rod (23) is fixedly connected above the two connecting plates (37) corresponding to the connecting frame (22), and the connecting frame (22) is slidably connected to the outer side of the fixed rod (23).

3. A 3D machining laser lathe according to claim 2, characterized in that: the adjusting component comprises a mounting box (4), and the mounting box (4) is fixedly connected above the inside of the connecting frame (22); a motor III (41) is fixedly connected below the inner part of the mounting box (4); the output end of the third motor (41) is rotationally connected with a second rotating shaft (42); a bevel gear III (43) which is symmetrically arranged is fixedly connected to the outer side of the second rotating shaft (42); a bevel gear IV (44) is meshed with the outer side of the bevel gear III (43); a second rotating rod (45) is fixedly connected to the middle of the fourth bevel gear (44), the upper part of the second rotating rod (45) penetrates through the connecting frame (22), and the second rotating rod (45) is rotatably connected to the bottom of the mounting box (4); an arc gear (46) is fixedly connected above the second rotating rod (45); a third rotating rod (48) is rotatably connected to the connecting frame (22) at a position corresponding to the arc gear (46); the position, corresponding to the arc gear (46), of the outer side of the rotating rod III (48) is fixedly connected with a face gear II (47), the face gear II (47) is intermittently meshed with the arc gear (46), and the face gear II (47) is alternately meshed with the two arc gears (46).

4. A 3D machining laser lathe according to claim 3, characterized in that: the lifting assembly comprises a motor II (3), and the motor II (3) is fixedly connected to the middle part above the supporting frame (12); the output end of the second motor (3) is rotationally connected with a first rotating shaft (31); the outer side of the first rotating shaft (31) is fixedly connected with a first bevel gear (32) which is symmetrically arranged; a bevel gear II (33) is meshed with the outer side of the bevel gear I (32); a rotating rod I (34) is fixedly connected to one side, away from the bevel gear I (32), of the bevel gear II (33); a first face gear (35) is fixedly connected to one side, far away from the bevel gear II (33), of the first rotating rod (34); a rack (36) is fixedly connected at the position of the connecting plate (37) corresponding to the first face gear (35), and the first face gear (35) is meshed with the rack (36).

5. The 3D machining laser lathe of claim 4, wherein: the support frame (12) is fixedly connected with symmetrically arranged fixed blocks (7) corresponding to the first rotating rod (34), and the first rotating rod (34) is rotationally connected in the fixed blocks (7).

6. The 3D machining laser lathe of claim 5, wherein: a fixed ring (49) is fixedly connected below the third rotating rod (48), and the fixed ring (49) is positioned in the mounting box (4); the sleeve (6) is fixedly connected to the position, corresponding to the fixing ring (49), in the mounting box (4), and the fixing ring (49) is rotatably connected in the sleeve (6).