CN114161156A - Drilling and tapping integrated laser pipe cutting machine capable of automatically feeding - Google Patents

Abstract

The invention belongs to the technical field of laser pipe cutting equipment, and particularly relates to a drilling and tapping integrated laser pipe cutting machine capable of automatically feeding materials. The device comprises a first base, an adjusting assembly, a pipe arrangement assembly, a feeding assembly, a second base, a bearing assembly, a pushing assembly, a drilling and tapping integrated machine and a laser pipe cutting part; the adjusting assembly and the pipe arranging assembly are fixedly arranged on the first base; the adjusting assembly is positioned at one end of the pipe arranging assembly; the feeding assembly comprises a first moving plate, a second motor and a second moving plate; the first moving plate is movably arranged at one end of the pipe arranging assembly, which is far away from the adjusting assembly; the second moving plate is movably arranged on the first moving plate, and a connecting column is fixedly connected below one end, far away from the first moving plate, of the second moving plate; through the arrangement, the drilling and tapping integrated laser pipe cutting machine capable of automatically feeding can automatically perform feeding operation without manual nursing during working, and labor cost is saved.

Description

Drilling and tapping integrated laser pipe cutting machine capable of automatically feeding

Technical Field

The invention belongs to the technical field of laser pipe cutting equipment, and particularly relates to a drilling and tapping integrated laser pipe cutting machine capable of automatically feeding materials.

Background

Laser cutting is to irradiate a workpiece with a focused high-power-density laser beam to quickly melt, vaporize and ablate the irradiated material or reach a burning point, and simultaneously blow off the molten material by means of a high-speed airflow coaxial with the beam, thereby realizing the cutting of the workpiece. Laser cutting is one of the thermal cutting methods.

A laser pipe cutting machine is one of laser cutting apparatuses. At present, many automatic feeding systems of laser pipe cutting machines at home and abroad can screen and separate pipes, and only one pipe is guaranteed to be sent to a processing machine tool. The number and orientation of the tubes is random as they are fed from the supply to the stacks. The position of tubular product on the work or material rest probably is that many tubular products are in the same place together, and the height of tubular product of putting together just colludes the mechanism at same height with the material, and to the big pipe (the cross section minor face is greater than 80mm), the material colludes the in-process that pushes away the material and probably interferes with tubular product, leads to the material to collude the card and dies, damages laser pipe cutting machine, in order to ensure laser pipe cutting machine's normal operating, needs the personnel of committee to attend to, very big waste the manpower.

Disclosure of Invention

Aiming at the problems, the invention provides a drilling and tapping integrated laser pipe cutting machine capable of automatically feeding, which comprises a first base, an adjusting assembly, a pipe arranging assembly, a feeding assembly, a second base, a bearing assembly, a pushing assembly, a drilling and tapping integrated machine and a laser pipe cutting part, wherein the first base is provided with a first hole;

the adjusting assembly and the pipe arranging assembly are fixedly arranged on the first base; the adjusting assembly is positioned at one end of the pipe arranging assembly; the feeding assembly comprises a first moving plate, a second motor and a second moving plate; the first moving plate is movably arranged at one end of the pipe arranging assembly, which is far away from the adjusting assembly;

the second moving plate is movably arranged on the first moving plate, and a connecting column is fixedly connected below one end, far away from the first moving plate, of the second moving plate; the second base is fixedly arranged on one side of the first base, on which the pipe arranging component is arranged; the bearing assembly is fixedly arranged on the second base; the pushing assembly is movably arranged on the second base and is positioned above the bearing assembly; a feed inlet of the drilling and tapping integrated machine is communicated with the bearing assembly; the laser pipe cutting part is arranged at one end, far away from the bearing assembly, of the drilling and tapping all-in-one machine.

Further, the pipe arranging assembly comprises a second air cylinder and a containing platform;

one ends of the bodies of the two groups of second cylinders are fixedly arranged on the first base through second supporting plates; one end of an output shaft of the second cylinder is in transmission connection with a second baffle, and the upper end of the second baffle is provided with a pressing plate; the containing table is positioned between the two groups of second baffles; the lower end of the second baffle is attached to the upper surface of the containing table in a sliding mode.

Furthermore, mounting plates are symmetrically arranged at two side ends of the containing platform; a first sliding rail is arranged on the mounting plate; the first moving plate is movably arranged on the first sliding rail.

Furthermore, the containing table is fixedly arranged on the first base through a third supporting plate; the upper surface of holding the platform is the inclined plane, the upper surface of holding the platform with the contained angle of first base is the acute angle.

Furthermore, hold the bench and still seted up first logical groove, one side that the conveyer belt was kept away from in first logical groove is provided with the third baffle.

Furthermore, the inner walls of two sides of the first through groove are respectively provided with a first clamping groove, and a clamping block is movably clamped in the first clamping groove through a spring; the two groups of clamping blocks are mutually symmetrical; the upper end face of the clamping block is an inclined plane, and the clamping block can be retracted into the first clamping groove.

Further, the feeding assembly further comprises a third motor; the connecting column is positioned in the first through groove; a second clamping groove is formed in one side of the connecting column, and a second through groove is formed in the connecting column; the second through groove penetrates through the connecting column and is communicated with the second clamping groove; a gear is rotatably mounted in the second clamping groove; and one end of an output shaft of the third motor is in transmission connection with the gear.

Furthermore, the feeding assembly also comprises a clamping part; the clamping part comprises a clamping plate and an arc-shaped plate, and the clamping plate is movably clamped in the second through groove; two ends of the clamping and connecting plate are respectively fixedly connected with the arc-shaped plate; a rack is arranged on one side, close to the second clamping groove, of the clamping plate; the rack is meshed with the gear.

Further, the bearing assembly comprises a first fixed plate, a fourth motor and a third moving plate; two groups of first fixing plates are respectively and fixedly arranged at two ends of the second base, and one end of the body of the fourth motor is fixedly arranged on the first fixing plates; a second ball screw is rotatably arranged between the two groups of first fixing plates; one end of an output shaft of the fourth motor is in transmission connection with the second ball screw; and the two groups of third moving plates are movably arranged on the second ball screw, and the internal threads of the two groups of third moving plates connected with the second ball screw are opposite.

Further, the bearing assembly also comprises a bearing roller; the carrying roller is rotatably arranged on the third moving plate, and a plurality of groups of third clamping grooves are formed in the carrying roller; the plurality of groups of third clamping grooves are in annular arrays; and a plurality of groups of balls are filled in each group of third clamping grooves.

The invention has the beneficial effects that:

1. the uneven pipes are adjusted through the adjusting assembly, so that two ends of the pipes in a plurality of groups are flush and enter the pipe arranging assembly; a plurality of groups of pipes are orderly arranged through the pipe arranging component and orderly enter the feeding component; the pipe is placed on the bearing assembly through the feeding assembly, and the bearing assembly is utilized to keep the pipe aligned with a feeding hole of the drilling and tapping all-in-one machine, so that the processing precision of the pipe is higher; the tubular product on the bearing component is pushed into a feeding hole of the drilling and tapping integrated machine through the pushing component, then the drilling and tapping integrated machine and the laser pipe cutting portion are utilized to process the tubular product, the steps do not need manual nursing, feeding operation can be automatically carried out, and labor cost is saved.

2. Through two sets of first cylinders, the two sets of first baffles of drive make the both ends of a plurality of groups of tubular product align to in carrying calandria subassembly through the conveyer belt, arrange in order uneven tubular product, make the material loading of tubular product more smooth and easy.

3. Through setting up the fixture block, when the vertical decurrent pressure of exerting on the fixture block surpasss the default, the fixture block is in retracting into first draw-in groove for tubular product is more orderly when leading to the groove through first.

4. When the two clamping plates are positioned in the two ends of the pipe, the horizontal height of the clamping plates starts to descend from the initial position by starting the second motor, so that the pipe is driven to descend until the pipe is placed on the bearing assembly through the clamping blocks. After that, the clamping plate is moved towards the direction close to the first moving plate through the third motor so as to be separated from the pipe, the second motor is started to enable the clamping plate to ascend to the initial height position, namely the pipe can be placed on the bearing assembly continuously, and the feeding efficiency of the pipe is higher.

5. Through having a plurality of groups of balls at every group third card inslot intussuseption for be located tubular product outer wall and a plurality of groups of ball sliding connection on two sets of takeover rollers, reduce the resistance that propelling movement subassembly promoted tubular product and produced, reduce energy consumption, reduction in production cost.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and drawings.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and those skilled in the art can also obtain other drawings according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an automatic-feeding drilling-tapping integrated laser pipe cutting machine according to an embodiment of the invention;

FIG. 2 illustrates a schematic structural diagram of an adjustment assembly of an embodiment of the present invention;

fig. 3 shows a schematic structural view of a gauntlet assembly of an embodiment of the invention;

fig. 4 is a schematic sectional view showing a holding table according to an embodiment of the present invention;

FIG. 5 shows a schematic structural view of a loading assembly of an embodiment of the invention;

FIG. 6 is a schematic structural diagram of a connecting column and a clamping portion according to an embodiment of the invention;

FIG. 7 shows a schematic structural view of a take-up assembly and a push assembly of an embodiment of the invention;

FIG. 8 shows a schematic structural diagram of a susceptor assembly according to an embodiment of the present invention;

FIG. 9 shows a schematic view of a construction of a uptake roller according to an embodiment of the present invention;

FIG. 10 shows a schematic structural diagram of a push assembly of an embodiment of the present invention;

FIG. 11 shows a schematic structural diagram of a drilling and tapping all-in-one machine according to an embodiment of the invention;

fig. 12 is a schematic cross-sectional structural diagram of the drilling and tapping all-in-one machine according to the embodiment of the invention.

In the figure: 1. a first base; 2. an adjustment assembly; 21. a first support plate; 22. a first cylinder; 23. a first baffle plate; 24. a conveyor belt; 3. a rack pipe assembly; 31. a second support plate; 32. a second cylinder; 33. a second baffle; 331. pressing a plate; 34. a third support plate; 35. a containing table; 351. a third baffle plate; 352. a first through groove; 353. a clamping block; 354. a first card slot; 36. mounting a plate; 361. a first slide rail; 4. a feeding assembly; 41. a first moving plate; 42. a first motor; 43. a first ball screw; 44. a second motor; 45. a second moving plate; 46. connecting columns; 461. a second card slot; 462. a second through groove; 47. a clamping part; 471. a clamping and connecting plate; 472. an arc-shaped plate; 473. a rack; 48. a gear; 49. a third motor; 5. a second base; 6. a receiving assembly; 61. a first fixing plate; 62. a fourth motor; 63. a second ball screw; 64. a third moving plate; 65. a receiving roller; 651. a third card slot; 652. a ball bearing; 7. a push assembly; 71. a second fixing plate; 72. a second slide rail; 73. a fifth motor; 74. supporting columns; 8. drilling and tapping integrated machines; 81. a body; 811. a third through groove; 812. a rotating assembly; 813. a roller; 814. a telescoping assembly; 815. a fourth card slot; 816. a fourth through groove; 82. drilling and tapping the assembly; 9. a pipe; 10. laser cutting the pipe portion.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the 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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The embodiment of the invention provides a drilling and tapping integrated laser pipe cutting machine capable of automatically feeding, which comprises a first base 1, an adjusting assembly 2, a pipe arranging assembly 3, a feeding assembly 4, a second base 5, a bearing assembly 6, a pushing assembly 7, a drilling and tapping integrated machine 8 and a laser pipe cutting part 10; drilling and tapping integrated machine, as an example, is shown in FIG. 1.

The adjusting assembly 2 and the pipe arranging assembly 3 are both fixedly arranged on the first base 1; the adjusting component 2 is positioned at one end of the pipe discharging component 3; the adjusting assembly 2 is used for adjusting the uneven pipes 9 in order, so that the pipes 9 can enter the pipe arranging assembly 3; the calandria component 3 is used for arranging the pipes 9 entering the calandria component 3.

The feeding assembly 4 is fixedly arranged at one end of the pipe arranging assembly 3 far away from the adjusting assembly 2; the second base 5 is fixedly arranged on one side of the first base 1, on which the calandria component 3 is arranged; the bearing component 6 is fixedly arranged on the second base 5; the pushing assembly 7 is movably mounted on the second base 5 and is positioned above the receiving assembly 6; the feed inlet of the drilling and tapping all-in-one machine 8 is communicated with the bearing assembly 6. The laser pipe cutting part 10 is arranged at one end, far away from the bearing assembly 6, of the drilling and tapping all-in-one machine 8.

The drilling and tapping integrated machine 8 is used for drilling and processing the pipe 9, and the laser pipe cutting part 10 is used for cutting the pipe 9 after drilling and processing.

The feeding assembly 4 is used for conveying the pipe 9 in the pipe discharging assembly 3 to the receiving assembly 6; the receiving assembly 6 is used for receiving pipes 9 with different sizes; the pushing assembly 7 is used for pushing the pipe 9 on the bearing assembly 6, enabling the pipe 9 to enter a feeding hole of the drilling and tapping all-in-one machine 8, and then the pipe 9 can be machined through the drilling and tapping all-in-one machine 8.

Illustratively, the uneven pipes 9 are adjusted by the adjusting assembly 2, so that two ends of the pipes 9 are flush and enter the pipe arranging assembly 3; a plurality of groups of pipes 9 are orderly arranged through the pipe arranging component 3 and orderly enter the feeding component 4; the pipe 9 is placed on the bearing component 6 through the feeding component 4, and the bearing component 6 is utilized to keep the pipe 9 aligned with the feeding hole of the drilling and tapping all-in-one machine 8, so that the processing precision of the pipe is higher; and then the pipe 9 on the bearing component 6 is pushed into a feeding hole of the drilling and tapping integrated machine 8 through the pushing component 7, then the drilling and tapping integrated machine 8 and the laser pipe cutting part 10 are utilized to process the pipe 9, the steps do not need manual nursing, the feeding operation can be automatically carried out, and the labor cost is saved.

The adjustment assembly 2 includes a first cylinder 22 and a conveyor 24, as shown, for example, in FIG. 2.

One ends of the bodies of the two groups of first air cylinders 22 are fixedly arranged on the first base 1 through a first supporting plate 21; one end of an output shaft of the first air cylinder 22 is connected with a first baffle plate 23 in a transmission way; the conveyor belt 24 is positioned between the two groups of first baffles 23; the conveyer belt 24 is used for carrying tubular product 9, through two sets of first cylinders 22, drives two sets of first baffles 23 and makes the both ends of a plurality of groups of tubular product 9 align to carry calandria subassembly 3 in through conveyer belt 24, arrange in order ragged tubular product 9, make the material loading of tubular product 9 more smooth and easy.

The calandria assembly 3 includes a second cylinder 32 and a holding platform 35, as shown in fig. 3 for example.

One end of the body of the two groups of second cylinders 32 is fixedly arranged on the first base 1 through a second supporting plate 31; one end of an output shaft of the second cylinder 32 is in transmission connection with a second baffle 33, and the upper end of the second baffle 33 is provided with a pressing plate 331; the press plate 331 is used to prevent the tube 9 from being piled up so that only a single layer of the tube 9 is located on the holding table 35.

The containing table 35 is positioned between the two groups of second baffle plates 33; the lower end of the second baffle 33 is attached to the upper surface of the containing table 35 in a sliding manner.

Mounting plates 36 are symmetrically arranged at two side ends of the containing table 35; the mounting plate 36 is provided with a first slide rail 361; the feeding assembly 4 is movably mounted on the first slide rail 361.

The holding table 35 is fixedly mounted on the first base 1 through a third supporting plate 34; the upper surface of the containing table 35 is an inclined surface, as shown in fig. 4 for example; the upper surface of holding platform 35 with the contained angle of first base 1 is the acute angle, is favorable to tubular product 9 to be higher the displacement to the lower department of level from the level on holding platform 35.

The containing table 35 is further provided with a first through groove 352, a third baffle 351 is arranged on one side, away from the conveyor belt 24, of the first through groove 352, and the third baffle 351 is used for preventing the pipe 9 from being separated from the containing table 35.

The inner walls of two sides of the first through groove 352 are both provided with a first clamping groove 354, and a clamping block 353 is movably clamped in the first clamping groove 354 through a spring; the two sets of latch 353 are symmetrical to each other.

The upper end surface of the clamping block 353 is an inclined surface, so that when vertical downward pressure is applied to the clamping block 353, the clamping block 353 can be retracted into the first clamping groove 354.

The first through groove 352 is used for allowing the tube 9 to enter and is blocked by the two groups of clamping blocks 353; when the vertical downward pressure applied on the fixture block 353 exceeds a preset value, the fixture block 353 is contracted into the first clamping groove 354, so that the tube 9 is more orderly when passing through the first through groove 352.

The feeding assembly 4 includes a first moving plate 41, a first motor 42, a second motor 44, a clamping portion 47 and a third motor 49, as shown in fig. 5 and 6 for example.

The lower end of the first moving plate 41 is movably mounted on the first slide rail 361 through a first motor 42; the two sets of first moving plates 41 are moved toward or away from each other by the first motor 42, so that the appropriate distance can be adjusted according to the lengths of the tubes 9.

A first ball screw 43 is rotatably mounted at one side of the two groups of first moving plates 41 which are close to each other; one end of the body of the second motor 44 is fixedly mounted on the first moving plate 41, and one end of the output shaft of the second motor 44 is in transmission connection with the first ball screw 43.

A second moving plate 45 is movably mounted on the first ball screw 43, a connecting column 46 is fixedly connected to the lower portion of one end, far away from the first ball screw 43, of the second moving plate 45, and a body of a third motor 49 is fixedly mounted above one end, far away from the first ball screw 43, of the second moving plate 45.

The connecting column 46 is located in the first through groove 352; a second clamping groove 461 is formed in one side of the connecting column 46, and a second through groove 462 is further formed in the connecting column 46; the second through slot 462 penetrates the connecting post 46 and communicates with the second engaging slot 461.

A gear 48 is rotatably mounted in the second slot 461; one end of the output shaft of the third motor 49 is in transmission connection with the gear 48.

The clamping portion 47 comprises a clamping plate 4711 and an arc-shaped plate 472, and the clamping plate 4711 is movably clamped in the second through groove 462; two ends of the clamping plate 4711 are fixedly connected with the arc-shaped plates 472 respectively; the curved plate 472 prevents the snap plate 4711 from disengaging from the second through-slot 462. A rack 473 is arranged on one side of the clamping plate 4711 close to the second clamping slot 461; the rack 473 is meshed with the gear 48.

Illustratively, by activating the third motor 49, the driving gear 48 rotates to move the snap-in plate 4711 in the second through-slot 462 in a direction away from the first moving plate 41 or in a direction close to the first moving plate 41, so that the snap-in plate 471 can enter the interior of the tube 9 or leave the interior of the tube 9.

When the two clamping plates 471 are located inside two ends of the tube 9, the second motor 44 is started to lower the horizontal height of the clamping plates 471 from the initial position, so as to drive the tube 9 to descend until the tube 9 passes through the clamping block 353, so that the tube 9 is placed on the receiving assembly 6. Then, the third motor 49 moves the snap plate 471 towards the direction close to the first moving plate 41 to separate the snap plate 471 from the tube 9, and the second motor 44 is started to raise the snap plate 471 to the initial height position, that is, the tube 9 can be continuously placed on the receiving component 6, so that the feeding efficiency of the tube 9 is higher.

The take-up assembly 6 includes a first fixed plate 61, a fourth motor 62, a third moving plate 64, and take-up rollers 65, as shown in fig. 7, 8, 9, and 10, for example.

Two groups of first fixing plates 61 are respectively and fixedly installed at two ends of the second base 5, and one end of the body of the fourth motor 62 is fixedly installed on the first fixing plates 61; (ii) a A second ball screw 63 is rotatably arranged between the two groups of first fixing plates 61; one end of the output shaft of the fourth motor 62 is in transmission connection with the second ball screw 63.

The two sets of third moving plates 64 are movably mounted on the second ball screw 63, and the internal threads of the two sets of third moving plates 64 connected with the second ball screw 63 are opposite, so that the two sets of third moving plates 64 approach to or separate from each other when the second ball screw 63 rotates.

The carrying roller 65 is rotatably mounted on the third moving plate 64, and a plurality of groups of third clamping grooves 651 are formed in the carrying roller 65; a plurality of sets of third card slots 651 are in an annular array; each group of third clamping grooves 651 is filled with a plurality of groups of balls 652, so that the outer wall of the pipe 9 positioned on the two groups of receiving rollers 65 is slidably connected with the plurality of groups of balls 652, the resistance generated by pushing the pipe 9 by the pushing assembly 7 is reduced, the energy consumption is reduced, and the production cost is reduced.

Illustratively, the two groups of take-up rollers 65 are close to or far away from each other by starting the fourth motor 62 so as to adapt to pipes 9 with different diameters, and the application range is wider.

The pushing assembly 7 comprises a second fixing plate 71, a second slide rail 72, a fifth motor 73 and a support column 74; the two sets of second fixed plates 71 are fixedly installed at two ends of the second base 5, and the upper ends of the two sets of second fixed plates 71 are fixedly connected through second sliding rails 72. The prop 74 is movably clamped on the second slide rail 72 through a fifth motor 73.

Illustratively, the fifth motor 73 can be started to drive the abutting columns 74 to push the pipes 9 on the two groups of receiving rollers 65, so that the pipes 9 can be conveyed into the feeding port of the drilling and tapping all-in-one machine 8, automatic feeding is realized, and the feeding efficiency is higher.

The drilling and tapping all-in-one machine 8 comprises a machine body 81 and a drilling and tapping assembly 82, as shown in fig. 11 and 12 for example.

A third through groove 811 is formed in the machine body 11, and the third through groove 811 is a feed inlet of the drilling and tapping all-in-one machine 8; a plurality of groups of fourth clamping grooves 815 are formed in the inner wall of the third through groove 811; the plurality of sets of fourth card slots 815 are in an annular array and are not less than four sets.

A body of the telescopic component 814 is fixedly installed in the fourth clamping groove 815; one end of an output shaft of the telescopic assembly 814 is in transmission connection with a rotating assembly 812, and two ends of the rotating assembly 812 are in transmission connection with rollers 813; the roller 813 is rotated by activating the rotating assembly 812.

A fourth through groove 816 is further formed in the top end of the body 81; the drilling and tapping assembly 82 is fixedly mounted above the machine body 81; and one end of the output shaft of the drilling and tapping assembly 82 can movably penetrate through the fourth through groove 816.

Illustratively, when the pipe 9 is pushed into the third through groove 811 by the prop 74, one end of the output shaft of the plurality of sets of telescopic assemblies 814 is extended to clamp the pipe 9; the tube 9 is limited. Thereafter, the drill-tap assembly 82 is activated to drill the pipe 9 through the fourth through slot 816. When other surfaces of the pipe 9 need to be drilled, the surface of the pipe 9 can be changed by only starting the rotating assembly 812. After the brill is attacked, will be located gyro wheel 813 of tubular product 9 first half and contract through flexible subassembly 814 for support post 74 can continue to promote tubular product 9 and get into laser pipe cutting portion 10 and cut, solved the difficult problem of drilling and tapping on the tubular product of being cut, practice thrift the process, improved production efficiency.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. The utility model provides an integrative laser pipe cutting machine is attacked to brill that can automatic feeding which characterized in that: the pipe cutting machine comprises a first base (1), an adjusting assembly (2), a pipe arranging assembly (3), a feeding assembly (4), a second base (5), a receiving assembly (6), a pushing assembly (7), a drilling and tapping integrated machine (8) and a laser pipe cutting part (10);

the adjusting assembly (2) and the pipe arranging assembly (3) are both fixedly arranged on the first base (1); the adjusting component (2) is positioned at one end of the pipe discharging component (3); the feeding assembly (4) comprises a first moving plate (41), a second motor (44) and a second moving plate (45); the first moving plate (41) is movably arranged at one end of the pipe arranging assembly (3) far away from the adjusting assembly (2);

the second moving plate (45) is movably mounted on the first moving plate (41), and a connecting column (46) is fixedly connected below one end, far away from the first moving plate (41), of the second moving plate (45); the second base (5) is fixedly arranged on one side of the first base (1) where the pipe arranging component (3) is arranged; the bearing assembly (6) is fixedly arranged on the second base (5); the pushing assembly (7) is movably arranged on the second base (5) and is positioned above the bearing assembly (6); a feed inlet of the drilling and tapping integrated machine (8) is communicated with the bearing assembly (6); the laser pipe cutting part (10) is arranged at one end, far away from the bearing assembly 6, of the drilling and tapping all-in-one machine 8.

2. The drilling and tapping integrated laser pipe cutting machine capable of automatically feeding materials as claimed in claim 1, wherein: the calandria component (3) comprises a second cylinder (32) and a containing platform (35);

one end of each of the bodies of the two groups of second cylinders (32) is fixedly arranged on the first base (1) through a second supporting plate (31); one end of an output shaft of the second air cylinder (32) is in transmission connection with a second baffle (33), and the upper end of the second baffle (33) is provided with a pressing plate (331); the containing table (35) is positioned between the two groups of second baffles (33); the lower end of the second baffle (33) is attached to the upper surface of the containing table (35) in a sliding mode.

3. The drilling and tapping integrated laser pipe cutting machine capable of automatically feeding materials as claimed in claim 2, wherein: mounting plates (36) are symmetrically arranged at two side ends of the containing table (35); a first sliding rail (361) is arranged on the mounting plate (36); the first moving plate (41) is movably mounted on the first sliding rail (361).

4. The drilling and tapping integrated laser pipe cutting machine capable of automatically feeding materials as claimed in claim 3, wherein: the containing table (35) is fixedly arranged on the first base (1) through a third supporting plate (34); the upper surface that holds platform (35) is the inclined plane, the upper surface that holds platform (35) with the contained angle of first base (1) is the acute angle.

5. The drilling and tapping integrated laser pipe cutting machine capable of automatically feeding materials as claimed in claim 4, wherein: the containing table (35) is further provided with a first through groove (352), and a third baffle (351) is arranged on one side, away from the conveying belt (24), of the first through groove (352).

6. The drilling and tapping integrated laser pipe cutting machine capable of automatically feeding materials as claimed in claim 5, wherein: the inner walls of two sides of the first through groove (352) are respectively provided with a first clamping groove (354), and a clamping block (353) is movably clamped in the first clamping groove (354) through a spring; the two groups of clamping blocks (353) are symmetrical; the upper end face of the clamping block (353) is an inclined face, and the clamping block (353) can be retracted into the first clamping groove (354).

7. The drilling and tapping integrated laser pipe cutting machine capable of automatically feeding materials as claimed in claim 1, wherein: the feeding assembly (4) further comprises a third motor (49); the connecting column (46) is positioned in the first through groove (352); a second clamping groove (461) is formed in one side of the connecting column (46), and a second through groove (462) is formed in the connecting column (46); the second through groove (462) penetrates through the connecting column (46) and is communicated with the second clamping groove (461); a gear (48) is rotatably arranged in the second clamping groove (461); one end of an output shaft of the third motor (49) is in transmission connection with the gear (48).

8. The drilling and tapping integrated laser pipe cutting machine capable of automatically feeding materials as claimed in claim 7, wherein: the feeding assembly (4) further comprises a clamping part (47); the clamping portion (47) comprises a clamping plate (471) and an arc-shaped plate (472), and the clamping plate (471) is movably clamped in the second through groove (462); two ends of the clamping and connecting plate (471) are fixedly connected with the arc-shaped plates (472) respectively; a rack (473) is arranged on one side, close to the second clamping groove (461), of the clamping plate (471); the rack (473) is meshed with the gear (48).

9. The drilling and tapping integrated laser pipe cutting machine capable of automatically feeding materials as claimed in claim 1, wherein: the bearing assembly (6) comprises a first fixed plate (61), a fourth motor (62) and a third moving plate (64); two groups of first fixing plates (61) are respectively and fixedly arranged at two ends of the second base (5), and one end of the body of the fourth motor (62) is fixedly arranged on the first fixing plates (61); a second ball screw (63) is rotatably arranged between the two groups of first fixing plates (61); one end of an output shaft of the fourth motor (62) is in transmission connection with a second ball screw (63); the two groups of third moving plates (64) are movably arranged on the second ball screw (63), and the internal threads of the two groups of third moving plates (64) connected with the second ball screw (63) are opposite.

10. The drilling-tapping integrated laser pipe cutting machine capable of automatically feeding materials as claimed in claim 9, wherein: the receiving assembly (6) further comprises a receiving roller (65); the carrying roller (65) is rotatably arranged on the third moving plate (64), and a plurality of groups of third clamping grooves (651) are formed in the carrying roller (65); a plurality of groups of third card slots (651) are in an annular array; each group of third clamping grooves (651) is filled with a plurality of groups of balls (652).

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