CN117260021B

CN117260021B - Auxiliary supporting device for laser cutting

Info

Publication number: CN117260021B
Application number: CN202311540133.3A
Authority: CN
Inventors: 张子红
Original assignee: Shenyang Locomotive And Rolling Stock Equipment Manufacturing Co ltd
Current assignee: Shenyang Locomotive And Rolling Stock Equipment Manufacturing Co ltd
Priority date: 2023-11-20
Filing date: 2023-11-20
Publication date: 2024-03-08
Anticipated expiration: 2043-11-20
Also published as: CN117260021A

Abstract

The invention belongs to the technical field of laser cutting, and discloses an auxiliary supporting device for laser cutting, which has the technical key points that: including the workstation, workstation surface fixed mounting has two sets of relative distribution's risers, and the common fixedly connected with roof in two sets of riser tops, roof diapire fixed mounting has laser cutter, and the fixed disk is installed in two sets of relative both sides wall rotations respectively, and two sets of risers are provided with the rotating assembly who is connected with the fixed disk jointly, and two sets of fixed disk relative both sides wall is provided with multiunit loading tray respectively, and the loading tray surface is provided with fixture, fixture is including splint and locating component, splint are including punch holder and lower plate, the workstation surface is provided with leads row mechanism, lead row mechanism including upset subassembly and automatic unloading subassembly, solved current manual work and installed and dismantlement to the work piece, can only cut a work piece once, problem that work efficiency is low.

Description

Auxiliary supporting device for laser cutting

Technical Field

The invention relates to the technical field of laser cutting, in particular to an auxiliary supporting device for laser cutting.

Background

Along with the development of society, laser cutting technology advances, laser emitted from a laser is focused into a laser beam with high power density through a light path system, the laser beam irradiates the surface of a workpiece, the workpiece reaches a melting point or a boiling point, and along with the movement of the relative position of the beam and the workpiece, a material is finally formed into a kerf, so that the aim of cutting is achieved.

When the laser cutting machine is used, the workpiece is clamped and fixed through the clamp, then the workpiece is cut by adjusting the height of the laser cutting machine, and after the workpiece is cut, the clamp is manually disassembled, so that the cut workpiece is taken down.

When the existing laser cutting mode is used, the workpiece is required to be installed and detached manually, only one workpiece can be cut at a time, and the working efficiency is low.

Disclosure of Invention

The present invention is directed to an auxiliary supporting device for laser cutting, so as to solve the above-mentioned problems in the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the utility model provides an auxiliary support device of laser cutting, includes the workstation, and workstation surface fixed mounting has two sets of relatively distributed risers, and two sets of riser tops are fixedly connected with roof jointly, roof diapire fixed mounting has laser cutter, and two sets of risers are relative both sides wall and are rotated respectively and install the fixed disk, and two sets of risers are provided with the rotating assembly who is connected with the fixed disk jointly, rotating assembly is used for controlling two sets of fixed disks at two sets of riser surface synchronous rotation, and two sets of fixed disk are relative both sides wall and are provided with multiunit loading disc respectively, multiunit loading disc is located the fixed disk surface and is annular equidistant distribution, the loading disc is connected with the fixed disk through pivot and fixed disk rotation, and the loading disc surface is provided with fixture, fixture is including splint and locating component, splint are including punch holder and lower plate, punch holder and lower plate are located the loading disc lateral wall and relative distribution, and punch holder length are greater than the lower plate, lower plate weight is greater than the punch holder, locating component is located the loading disc lateral wall and is connected with punch holder and lower, locating component is used for adjusting punch holder and the punch holder, the guide plate is located the upper plate and lower plate, the relative position between fixed disk surface of face-down plate and the fixed part is used for unloading, the automatic part is located the relative position of unloading with the fixed disc, the workstation is used for setting up and is located the relative position of the unloading part between the face-down plate, the surface is fixed with the surface of the unloading assembly.

As a further scheme of the invention: the rotating assembly comprises a first gear ring fixedly arranged on the annular side wall of the fixed disc, two groups of vertical plates are jointly rotated and provided with rotating rods, the surfaces of the rotating rods are fixedly provided with transmission fluted discs, the transmission fluted discs are meshed with the first gear ring, and one ends of the rotating rods extend to the outer sides of the vertical plates and are connected with motors.

As a further scheme of the invention: the positioning assembly comprises two rows of sliding grooves which are formed in the surface of the bearing disc and are distributed oppositely, sliding blocks are slidably mounted in the sliding grooves, extrusion springs connected with the sliding blocks are fixedly mounted in the sliding grooves, and a plurality of groups of sliding blocks extend to the outer sides of the sliding grooves and are fixedly connected with the upper clamping plate and the lower clamping plate respectively.

As a further scheme of the invention: the overturning assembly comprises a second gear ring fixedly arranged on the annular side wall of the bearing disc, a vertical rod is fixedly arranged on the surface of the workbench, and a rack meshed with the second gear ring is fixedly arranged at the top end of the vertical rod.

As a further scheme of the invention: the automatic discharging assembly comprises a baffle which is rotatably arranged on the surface of the workbench and matched with the upper clamping plate, positioning springs positioned on two sides of the baffle are fixedly arranged on the surface of the workbench, and the telescopic ends of the positioning springs are fixedly connected with the side walls of the baffle.

As a further scheme of the invention: the surface of the workbench is provided with a discharge groove in an inclined state.

As still further aspects of the invention: the two opposite side walls of the upper clamping plate and the lower clamping plate are respectively provided with a positioning arc groove.

Compared with the prior art, the invention has the beneficial effects that: the clamping mechanism composed of the positioning component and the clamping plate is matched with the guide mechanism composed of the overturning component and the automatic discharging component, so that batch workpieces can be continuously supported, positioned and cut, the workpieces can be automatically taken out after being cut, and the cutting efficiency is effectively improved. The problem of current manual work install and dismantle the work piece, can only cut a work piece once, work efficiency is low is solved.

Drawings

Fig. 1 is a schematic perspective view of an auxiliary supporting device for laser cutting according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of a fixing disc and a connection structure thereof in an auxiliary supporting device for laser cutting according to an embodiment of the present invention.

Fig. 3 is an enlarged schematic view of the structure of fig. 2 a.

Fig. 4 is a schematic plan view of an auxiliary supporting device for laser cutting according to an embodiment of the present invention.

Fig. 5 is an enlarged schematic view of the structure of fig. 4 a.

Wherein: 1-workbench, 2-riser, 3-roof, 4-laser cutter, 5-fixed disk, 6-rotating component, 61-rotating rod, 62-driving fluted disc, 63-first gear ring, 7-bearing disk, 8-clamping mechanism, 81-clamping plate, 811-upper clamping plate, 812-lower clamping plate, 82-positioning component, 821-chute, 822-slider, 823-extrusion spring, 9-guide and discharge mechanism, 91-turnover component, 911-second gear ring, 912-vertical rod, 913-rack, 92-automatic discharge component, 921-baffle, 922-positioning spring, 10-discharge slot, 11-positioning arc slot.

Detailed Description

It should be noted that, without conflict, the embodiments of the present invention and features of the embodiments may be combined with each other.

Specific implementations of the invention are described in detail below in connection with specific embodiments.

As shown in fig. 1, fig. 2 and fig. 4, a structure diagram of an auxiliary supporting device for laser cutting according to an embodiment of the present invention includes a workbench 1, two sets of relatively distributed risers 2 are fixedly installed on the surface of the workbench 1, top ends of the two sets of risers 2 are fixedly connected with a top plate 3, a laser cutter 4 is fixedly installed on a bottom wall of the top plate 3, two opposite side walls of the two sets of risers 2 are respectively rotatably installed with a fixed disk 5, the two sets of risers 2 are jointly provided with a rotating assembly 6 connected with the fixed disk 5, the rotating assembly 6 is used for controlling the two sets of fixed disks 5 to synchronously rotate on the surfaces of the two sets of risers 2, two opposite side walls of the two sets of fixed disks 5 are respectively provided with a plurality of bearing disks 7, the plurality of bearing disks 7 are located on the surfaces of the fixed disks 5 and are distributed in a ring shape at equal intervals, the bearing disks 7 are rotatably connected with the fixed disks 5 through a rotating shaft, the surface of the carrier plate 7 is provided with a clamping mechanism 8, the clamping mechanism 8 comprises a clamping plate 81 and a positioning component 82, the clamping plate 81 comprises an upper clamping plate 811 and a lower clamping plate 812, the upper clamping plate 811 and the lower clamping plate 812 are positioned on the side wall of the carrier plate 7 and are distributed oppositely, the length of the upper clamping plate 811 is larger than that of the lower clamping plate 812, the weight of the lower clamping plate 812 is larger than that of the upper clamping plate 811, the positioning component 82 is positioned on the side wall of the carrier plate 7 and is connected with the upper clamping plate 811 and the lower clamping plate 812, the positioning component 82 is used for adjusting the relative position between the upper clamping plate 811 and the lower clamping plate 812, the surface of the workbench 1 is provided with a guide and exhaust mechanism 9, the guide and exhaust mechanism 9 comprises a turnover component 91 and an automatic discharging component 92, the turnover component 91 is positioned on the surface of the workbench 1 and is connected with the carrier plate 7, the turnover component 91 is used for controlling the carrier plate 7 to rotate on the surface of the fixed plate 5, the automatic discharging component 92 is located on the surface of the workbench 1 and is matched with the upper clamping plate 811, and the automatic discharging component 92 is used for adjusting the relative position between the upper clamping plate 811 and the lower clamping plate 812 at the bottom of the fixed disc 5.

When in use, the rotating component 6 controls the fixed disks 5 at the side walls of the two groups of vertical plates 2 to synchronously rotate, the fixed disks 5 drive the multiple groups of bearing disks 7 to synchronously rotate so as to drive the clamping plates 81 on the surfaces of the bearing disks 7 to synchronously rotate, the lower clamping plates 812 are always in a horizontal state and are positioned below the upper clamping plates 811 when the bearing disks 7 rotate due to the fact that the weight of the lower clamping plates 812 is larger than that of the upper clamping plates 811, when the fixed disks 5 slowly rotate, a worker manually inserts workpieces to be cut between the upper clamping plates 811 and the lower clamping plates 812 on the surfaces of the two groups of bearing disks 7, the positioning component 82 applies thrust to the upper clamping plates 811 and the lower clamping plates 812, the upper clamping plates 811 and the lower clamping plates 812 are mutually matched, the workpieces can be stably clamped and positioned, when the fixed disks 5 drive the bearing disks 7 to rotate to the highest position, the laser cutter 4 can automatically cut the workpieces between the two groups of bearing disks 7, after the workpiece is cut, the upper clamping plate 811 and the lower clamping plate 812 continuously clamp the cut workpiece, the fixed plate 5 continuously rotates to further drive the bearing plate 7 to synchronously rotate, the bearing plate 7, the upper clamping plate 811 and the lower clamping plate 812 are mutually matched to drive the cut workpiece to continuously rotate, when the bearing plate 7 is about to rotate to the bottom of the fixed plate 5, the overturning component 91 controls the bearing plate 7 to rotate ninety degrees on the surface of the fixed plate 5, the bearing plate 7 and the positioning component 82 are mutually matched to control the upper clamping plate 811 and the lower clamping plate 812 to rotate to a vertical state, when the upper clamping plate 811 and the lower clamping plate 812 rotate to a vertical state, the upper clamping plate 811 is pushed by the automatic unloading component 92 to move in a direction away from the lower clamping plate 812, the workpiece between the upper clamping plate 811 and the lower clamping plate 812 can automatically drop, the fixed plate 5 continuously rotates, the bearing plate 7 continuously rotates on the surface of the fixed plate 5, the upper and lower clamping plates 811 and 812 are restored to the horizontal state, and the clamping and cutting process can be continued for the batch of workpieces.

As shown in fig. 1 and 4, as a preferred embodiment of the present invention, the rotating assembly 6 includes a first gear ring 63 fixedly mounted on the annular side wall of the fixed disc 5, the two sets of risers 2 are rotatably mounted with a rotating rod 61, the surface of the rotating rod 61 is fixedly mounted with a driving fluted disc 62, the driving fluted disc 62 is meshed with the first gear ring 63, and one end of the rotating rod 61 extends to the outer side of the risers 2 and is connected with a motor.

When in use, the motor drives the rotating rod 61 to rotate so as to drive the two groups of transmission fluted discs 62 to synchronously rotate, the transmission fluted discs 62 are meshed with the first gear ring 63 for transmission, and the two groups of fixed discs 5 are driven to rotate at the side walls of the two groups of vertical plates 2 respectively.

As shown in fig. 1, 2, 3, 4 and 5, as a preferred embodiment of the present invention, the positioning assembly 82 includes two rows of sliding grooves 821 which are formed on the surface of the carrier plate 7 and are distributed oppositely, sliding blocks 822 are slidably mounted in the sliding grooves 821, compression springs 823 connected with the sliding blocks 822 are fixedly mounted in the sliding grooves 821, and a plurality of groups of sliding blocks 822 extend to the outer side of the sliding grooves 821 and are fixedly connected with the upper clamping plate 811 and the lower clamping plate 812 respectively.

The sliding groove 821 and the sliding block 822 are matched with each other, the upper clamping plate 811 and the lower clamping plate 812 can be installed on the side wall of the bearing disc 7, the sliding block 822 moves in the sliding groove 821, the relative distance between the upper clamping plate 811 and the lower clamping plate 812 can be conveniently adjusted, workpieces with different thickness sizes can be clamped, in the clamping process, the extrusion spring 823 applies thrust to the sliding block 822, and then applies thrust to the upper clamping plate 811 and the lower clamping plate 812 respectively, and the upper clamping plate 811 and the lower clamping plate 812 can stably clamp and position the workpieces.

As shown in fig. 1, 3, 4 and 5, as a preferred embodiment of the present invention, the turnover assembly 91 includes a second gear ring 911 fixedly mounted on the annular side wall of the carrier 7, a vertical rod 912 is fixedly mounted on the surface of the table 1, and a rack 913 engaged with the second gear ring 911 is fixedly mounted on the top end of the vertical rod 912.

The fixed disk 5 drives the carrier disk 7 to rotate synchronously, in the rotating process, because the weight of the lower clamping plate 812 is greater than that of the upper clamping plate 811, the upper clamping plate 811 and the lower clamping plate 812 are in a horizontal state, when the second gear ring 911 on the surface of the carrier disk 7 is meshed with the rack 913, the carrier disk 7 rolls along the surface of the rack 913, the upper clamping plate 811 and the lower clamping plate 812 rotate from the horizontal state to the vertical state, and after the second gear ring 911 is separated from the rack 913, the carrier disk 7 rotates on the surface of the fixed disk 5, and the upper clamping plate 811 and the lower clamping plate 812 rotate again to the horizontal state.

As shown in fig. 1, 2, 4 and 5, as a preferred embodiment of the present invention, the automatic discharging assembly 92 includes a baffle plate 921 rotatably mounted on a surface of the table 1 and engaged with the upper plate 811, positioning springs 922 disposed on two sides of the baffle plate 921 are fixedly mounted on the surface of the table 1, and telescopic ends of the positioning springs 922 are fixedly connected with side walls of the baffle plate 921.

Initially, the positioning spring 922 supports and positions the baffle 921 such that the baffle 921 is in a vertical state, when the upper clamp plate 811 is rotated from a horizontal state to a vertical state, the bottom end of the upper clamp plate 811 contacts the baffle 921, the baffle 921 blocks the upper clamp plate 811, at this time, the distance between the upper clamp plate 811 and the lower clamp plate 812 increases, and the cut workpiece can automatically fall from between the upper clamp plate 811 and the lower clamp plate 812.

As shown in fig. 2 and 4, as a preferred embodiment of the present invention, the surface of the table 1 is provided with a discharge groove 10 in an inclined state.

The cut workpiece falls into the discharge groove 10, the discharge groove 10 can automatically guide and discharge the workpiece, and the workpiece can be guided and discharged outside the workbench 1.

As shown in fig. 2 and 5, as a preferred embodiment of the present invention, two side walls of the upper clamping plate 811 opposite to the lower clamping plate 812 are respectively provided with positioning arc grooves 11.

When the cylindrical workpiece is cut by laser, the workpiece is placed in the positioning arc groove 11, and the upper and lower clamping plates 811 and 812 can stably clamp and position the workpiece.

The working principle of the invention is as follows: when in use, the motor drives the rotating rod 61 to rotate so as to drive the two groups of transmission fluted discs 62 to synchronously rotate, the transmission fluted discs 62 are meshed with the first gear ring 63 for transmission, and the two groups of fixed discs 5 are driven to rotate at the side walls of the two groups of vertical plates 2 respectively. The fixed disk 5 drives the multiple groups of bearing disks 7 to synchronously rotate so as to drive the clamping plates 81 on the surfaces of the bearing disks 7 to synchronously rotate, and because the weight of the lower clamping plate 812 is greater than that of the upper clamping plate 811, the lower clamping plate 812 is always in a horizontal state and is positioned below the upper clamping plate 811 when the bearing disks 7 rotate, and when the fixed disk 5 slowly rotates, a worker manually inserts workpieces to be cut between the upper clamping plate 811 and the lower clamping plate 812 on the surfaces of the two groups of bearing disks 7, and the extrusion springs 823 apply thrust to the sliding blocks 822 so as to respectively apply thrust to the upper clamping plate 811 and the lower clamping plate 812, so that the upper clamping plate 811 and the lower clamping plate 812 can stably clamp and position the workpieces. When the fixed disk 5 drives the carrying disk 7 to rotate to the highest position, the laser cutter 4 can automatically cut workpieces between the two groups of carrying disks 7, after the workpieces are cut, the upper clamping plate 811 and the lower clamping plate 812 continue to clamp the cut workpieces, the fixed disk 5 continuously rotates to drive the carrying disk 7 to synchronously rotate, the carrying disk 7, the upper clamping plate 811 and the lower clamping plate 812 are mutually matched to drive the cut workpieces to continuously rotate, when the carrying disk 7 is about to rotate to the bottom of the fixed disk 5, the second gear ring 911 on the surface of the carrying disk 7 is meshed with the rack 913, the carrying disk 7 rolls along the surface of the rack 913, the upper clamping plate 811 and the lower clamping plate 812 rotate from a horizontal state to a vertical state, when the upper clamping plate 811 rotates from the horizontal state to the vertical state, the bottom end of the upper clamping plate 811 contacts with the baffle 921, at the moment, the distance between the upper clamping plate 811 and the lower clamping plate 812 is increased, and the cut workpieces can automatically fall off from the upper clamping plate 811 to the lower clamping plate 812. After the second ring gear 911 is separated from the rack 913, the carrier plate 7 rotates on the surface of the fixed plate 5, and the upper and lower clamping plates 811 and 812 are rotated again to the horizontal state. The clamping and cutting process may continue for a batch of workpieces.

While the preferred embodiments of the present invention have been described in detail, the present invention is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art.

Claims

1. The auxiliary supporting device for laser cutting comprises a workbench, two groups of relatively distributed risers are fixedly arranged on the surface of the workbench, a top plate is fixedly connected to the top ends of the two groups of risers together, a laser cutter is fixedly arranged on the bottom wall of the top plate, the auxiliary supporting device is characterized in that fixed disks are respectively rotatably arranged on two opposite side walls of the two groups of risers, rotating components connected with the fixed disks are jointly arranged on the two groups of risers, the rotating components are used for controlling the two groups of fixed disks to synchronously rotate on the surfaces of the two groups of risers, the rotating components comprise a first gear ring fixedly arranged on the annular side wall of the fixed disks, rotating rods are fixedly arranged on the surfaces of the two groups of risers in a rotating mode, a transmission fluted disc is fixedly arranged on the surfaces of the rotating rods and is meshed with the first gear ring, one end of each rotating rod extends to the outer side of each riser and is connected with a motor, a plurality of groups of bearing disks are respectively arranged on two opposite side walls of the two groups of fixed disks, the bearing plates are arranged on the surface of the fixed plate in an annular equidistant mode, the bearing plates are rotationally connected with the fixed plate through rotating shafts, the surfaces of the bearing plates are provided with clamping mechanisms, the clamping mechanisms comprise clamping plates and positioning components, the clamping plates comprise upper clamping plates and lower clamping plates, the upper clamping plates and the lower clamping plates are arranged on the side walls of the bearing plates and are distributed oppositely, the lengths of the upper clamping plates are larger than those of the lower clamping plates, the weights of the lower clamping plates are larger than those of the upper clamping plates, the positioning components are arranged on the side walls of the bearing plates and are connected with the upper clamping plates and the lower clamping plates, the positioning components are used for adjusting the relative positions between the upper clamping plates and the lower clamping plates, each positioning component comprises two rows of sliding grooves which are arranged on the surfaces of the bearing plates and are distributed oppositely, sliding blocks are arranged in the sliding grooves in a sliding way, and a compression spring connected with the sliding blocks is fixedly arranged in each sliding groove, the sliding blocks extend to the outer side of the sliding grooves and are fixedly connected with the upper clamping plate and the lower clamping plate respectively, the guide and discharge mechanism is arranged on the surface of the workbench and comprises a turnover assembly and an automatic discharge assembly, the turnover assembly is located on the surface of the workbench and is connected with the bearing disc, the turnover assembly is used for controlling the bearing disc to rotate on the surface of the fixed disc, the turnover assembly comprises a second gear ring fixedly mounted on the annular side wall of the bearing disc, a vertical rod is fixedly mounted on the surface of the workbench, racks meshed with the second gear ring are fixedly mounted on the top end of the vertical rod, the automatic discharge assembly is located on the surface of the workbench and is matched with the upper clamping plate, the automatic discharge assembly is used for adjusting the relative position between the upper clamping plate and the lower clamping plate at the bottom of the fixed disc, the automatic discharge assembly comprises a baffle which is rotatably mounted on the surface of the workbench and is matched with the upper clamping plate, positioning springs located on two sides of the baffle are fixedly mounted on the surface of the workbench, and the telescopic ends of the positioning springs are fixedly connected with the side walls of the baffle.

2. An auxiliary support device for laser cutting according to claim 1, wherein the table surface is provided with a discharge slot in an inclined state.

3. The auxiliary supporting device for laser cutting according to claim 1, wherein two opposite side walls of the upper clamping plate and the lower clamping plate are respectively provided with a positioning arc groove.