CN217571310U - Double-deck bowl duplex position laser-beam welding machine of stainless steel - Google Patents

Abstract

The utility model relates to a laser welding equipment technical field, concretely relates to double-deck bowl duplex position laser-beam welding machine of stainless steel, including the workstation, connect in the speed reduction actuating mechanism of the bottom of workstation, set up in the rolling disc that the top of workstation and be connected with speed reduction actuating mechanism's output, connect in the double-deck bowl processing tool of stainless steel at the top of rolling disc, run through speed reduction actuating mechanism and rolling disc in proper order and support and lean on the pushing equipment in the double-deck bowl processing tool of stainless steel bottom, connect in the laser head adjustment mechanism at the top of workstation, connect in the laser head body of laser head adjustment mechanism and connect in the hold-down mechanism at the top of workstation, double-deck bowl processing tool of stainless steel is used for holding the double-deck bowl of stainless steel, the laser head body is used for the bowl mouth border of the double-deck bowl of laser welding stainless steel, hold-down mechanism and the cooperation of the double-deck bowl of stainless steel are used for pressing from both sides tight double-deck bowl of stainless steel. The equipment saves the cost and improves the production efficiency.

Description

Double-deck bowl duplex position laser-beam welding machine of stainless steel

Technical Field

The utility model relates to a laser welding equipment technical field, concretely relates to double-deck bowl duplex position laser-beam welding machine of stainless steel.

Background

Laser welding machines, also commonly called laser welding machines and laser welding machines, are machines used in material processing laser welding.

Generally welding circular arc/round metal products such as stainless steel double layer bowls; most adopt the robot to weld, but adopt the robot welding, its design manufacturing cost is high, and it is big to occupy the position, welds circular-arc product and produces the obstacle easily, and different products still need debug the programming, and the structure is more complicated, still need be equipped with comparatively professional technical staff and maintain.

Disclosure of Invention

In order to overcome the defects and deficiencies in the prior art, the utility model aims to provide a double-layer bowl double-station laser welding machine for stainless steel.

The purpose of the utility model is realized through the following technical scheme: the utility model provides a double-deck bowl duplex position laser-beam welding machine of stainless steel, includes the workstation, connects in the speed reduction actuating mechanism of the bottom of workstation, set up in the top of workstation and the rolling disc of being connected with speed reduction actuating mechanism's output, connect in the double-deck bowl processing tool of stainless steel at the top of rolling disc, run through speed reduction actuating mechanism and rolling disc in proper order and support and lean on the pushing equipment in the double-deck bowl processing tool of stainless steel bottom, connect in the laser head adjustment mechanism at the top of workstation, connect in the laser head body of laser head adjustment mechanism and connect in the hold-down mechanism at the top of workstation, double-deck bowl processing tool of stainless steel is used for holding the double-deck bowl of stainless steel, the laser head body is used for the bowl mouth of a river border of the double-deck bowl of laser welding stainless steel, hold-down mechanism and the cooperation of the double-deck bowl of stainless steel are used for pressing from both sides tight double-deck bowl of stainless steel.

Preferably, the stainless steel double-layer bowl processing jig comprises an outer layer jig connected to the top of the rotating disc and an inner layer jig rotatably connected to the output end of the pressing mechanism, and the outer layer jig and the inner layer jig are matched to be used for clamping and setting the stainless steel double-layer bowl.

Preferably, the pressing mechanism comprises a connecting seat connected to the workbench, a pressing cylinder connected to the top of the connecting seat, a sliding assembly connected to the side wall of the connecting seat, and a pressing piece connected with the sliding assembly, an output end of the pressing cylinder penetrates through the connecting seat and is connected with the pressing piece, and the pressing piece is rotatably connected with the inner layer jig.

Preferably, a hollow connecting shaft extends from the bottom of the pressing piece, a rotating shaft extending into the hollow connecting shaft is convexly extended from the top of the inner-layer jig, a bearing is sleeved on the rotating shaft, and the rotating shaft is rotatably connected with the hollow connecting shaft through the bearing; the sliding assembly comprises a first sliding rail fixedly connected to the side wall of the connecting seat and a first sliding block slidably connected with the first sliding rail, and the pressing piece is fixedly connected with the first sliding block.

Preferably, laser head adjustment mechanism include with the Y axle that the workstation is connected is adjusted the seat, is adjusted the Y axle adjusting part that the lateral wall of seat is connected with the Y axle, is adjusted the seat with the X axle that Y axle adjusting part is connected, is adjusted the X axle adjusting part that the lateral wall of seat is connected with the X axle, the theta axle adjusting part who is connected with X axle adjusting part's lateral wall and the laser head connecting block of being connected with theta axle adjusting part, laser head connecting block and this body coupling of laser head.

Preferably, the Y-axis adjusting assembly comprises a second slide rail fixedly connected with the side wall of the Y-axis adjusting seat, a second slide block connected with the second slide rail in a sliding manner, a first connecting block connected with the second slide block, a first lead screw stepping motor connected with the top of the Y-axis adjusting seat, and a first lead screw nut in threaded fit with the output end of the first lead screw stepping motor, and the first lead screw nut and the X-axis adjusting seat are fixedly connected with the first connecting block.

Preferably, the X-axis adjusting assembly comprises a third slide rail fixedly connected with the side wall of the X-axis adjusting seat, a third slide block slidably connected with the third slide rail, a second connecting block connected with the third slide block, a second lead screw stepping motor connected with the top of the X-axis adjusting seat, and a second lead screw nut in threaded fit with the output end of the second lead screw stepping motor, and the second lead screw nut and the θ -axis adjusting assembly are both fixedly connected with the second connecting block.

Preferably, the theta axis adjusting component comprises a hollow clamping sleeve and a rotary adjusting seat clamped in the middle of the hollow clamping sleeve, and the rotary adjusting seat is fixedly connected with the laser head connecting block.

Preferably, the speed reduction driving mechanism comprises a servo motor, a speed reducer in transmission connection with the output end of the servo motor, and a hollow rotating shaft connected with the output end of the speed reducer, and the hollow rotating shaft is fixedly connected with the rotating disc.

Preferably, the pushing mechanism comprises a cylinder fixing seat connected with the bottom of the speed reducer, a pushing cylinder connected with the cylinder fixing seat, and a pushing rod connected with the output end of the pushing cylinder, and the pushing rod penetrates through the hollow rotating shaft and the rotating disc and abuts against the bottom of the stainless steel double-layer bowl processing jig.

The beneficial effects of the utility model reside in that: the utility model discloses a double-deck bowl duplex position laser-beam welding machine of stainless steel, during the use, put into the double-deck bowl processing tool of stainless steel to stainless steel bowl skin, put stainless steel bowl skin to stainless steel bowl inlayer equidirectional again in, then start hold-down mechanism and compress tightly the double-deck bowl of stainless steel, the distance of laser head body is fixed in the adjustment of laser head adjustment mechanism, the bowl mouth border of the double-deck bowl of stainless steel is foldd to laser head body welding seam, the laser head begins the light-emitting and the reduction drive mechanism drive rolling disc rotates, drive the double-deck bowl processing tool of stainless steel and the double-deck bowl of stainless steel that is pressed from both sides tightly rotates the circumference welding in order to realize the double-deck bowl of stainless steel, the laser head body stops the light-emitting after the welding is accomplished, hold-down mechanism resets, pushing mechanism moves and promotes the double-deck bowl of stainless steel and rises, can take out the double-deck bowl of stainless steel, the welding is accomplished. For products of the same type and different sizes, the laser head can be directly welded only by adjusting the distance of the laser head body or replacing a stainless steel double-layer bowl processing jig; compared with a robot, the robot has the advantages that the utilization rate of the equipment is high, the size is small, the occupied position space is small, multiple equipment can be placed in the same position space, double-station arrangement can be realized, products can be taken and placed simply and conveniently, redundant actions are not needed, the cost is saved, and the production efficiency is improved.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a cross-sectional view of the present invention;

FIG. 3 is an enlarged schematic view of A in FIG. 2;

fig. 4 is a schematic structural diagram of the laser head adjusting mechanism of the present invention;

fig. 5 is an exploded schematic view of the laser head adjusting mechanism of the present invention.

The reference signs are:

1. a work table;

2. a deceleration drive mechanism; 21. a servo motor; 22. a speed reducer; 23. a hollow rotating shaft;

3. rotating the disc;

4. a stainless steel double-layer bowl processing jig; 41. an outer layer fixture; 42. an inner layer jig;

5. a material pushing mechanism; 51. a cylinder fixing seat; 52. a material pushing cylinder; 53. a material pushing rod;

6. a laser head adjusting mechanism; 61. a Y-axis adjusting seat; 62. a Y-axis adjustment assembly; 621. a second slide rail; 622. a second slider; 623. a first connection block; 624. a first lead screw stepping motor; 625. a first lead screw nut; 63. an X-axis adjusting seat; 64. an X-axis adjustment assembly; 641. a third slide rail; 642. a third slider; 643. a second connecting block; 644. a second lead screw stepping motor; 645. a second feed screw nut; 65. a theta axis adjustment assembly; 651. a hollow clamping sleeve; 652. rotating the adjusting seat; 66. a laser head connecting block;

7. a laser head body;

8. a hold-down mechanism; 81. a connecting seat; 82. a pressing cylinder; 83. a compression member; 84. a first slide rail; 85. a first slider;

9. a hollow connecting shaft;

10. a rotating shaft;

11. a bearing;

12. an inner layer of a stainless steel bowl;

13. the outer layer of the stainless steel bowl.

Detailed Description

In order to facilitate understanding of those skilled in the art, the present invention will be further described with reference to the following examples and drawings, which are not intended to limit the present invention.

As shown in fig. 1-5, a double-deck bowl duplex position laser-beam welding machine of stainless steel, including workstation 1, connect in the speed reduction actuating mechanism 2 of the bottom of workstation 1, set up in the rolling disc 3 that the top of workstation 1 and be connected with the output of speed reduction actuating mechanism 2, connect in the double-deck bowl processing tool 4 of stainless steel at the top of rolling disc 3, run through speed reduction actuating mechanism 2 and rolling disc 3 in proper order and support and lean on pushing equipment 5 in the double-deck bowl processing tool 4 bottom of stainless steel, connect in the laser head adjustment mechanism 6 at the top of workstation 1, connect in the laser head body 7 of laser head adjustment mechanism 6 and connect in the hold-down mechanism 8 at the top of workstation 1, double-deck bowl processing tool 4 of stainless steel is used for holding the double-deck bowl of stainless steel, laser head body 7 is used for the bowl mouth border of the double-deck bowl of laser welding stainless steel, hold-down mechanism 8 and the cooperation of double-deck bowl processing tool 4 of stainless steel are used for pressing from both sides tight double-deck bowl of stainless steel tightly.

When the laser welding machine is used, the outer stainless steel bowl layer 13 is placed in the stainless steel bowl processing jig 4, the inner stainless steel bowl layer 12 is placed in the outer stainless steel bowl layer 13 in the same direction, the pressing mechanism 8 is started to press the stainless steel bowl layer, the laser head adjusting mechanism 6 adjusts and fixes the distance of the laser head body 7, the bowl opening edge of the stainless steel bowl layer is folded by the welding line of the laser head body 7, the laser head starts to emit light, the speed reduction driving mechanism 2 drives the rotating disc 3 to rotate, the stainless steel bowl processing jig 4 and the clamped stainless steel bowl layer are driven to rotate to achieve circumferential welding of the stainless steel bowl layer, the laser head body 7 stops emitting light after welding is completed, the pressing mechanism 8 resets, the material pushing mechanism 5 acts and pushes the stainless steel bowl layer to rise, the stainless steel bowl layer can be taken out, and welding is completed. For products with the same type and different sizes, the direct welding can be realized only by adjusting the distance of the laser head body 7 or replacing the stainless steel double-layer bowl processing jig 4; compared with a robot, the robot has the advantages that the utilization rate of the equipment is high, the size is small, the occupied position space is small, multiple equipment can be placed in the same position space, double stations can be arranged, products can be taken and placed conveniently, redundant actions are not needed, the cost is saved, and the production efficiency is improved. Furthermore, the double-station laser welding machine for the stainless steel double-layer bowl adopts double-station arrangement, a product welded at the second station can be taken out or clamped before welding while the first station is welded, the steps are repeated, and when the second station starts welding, the product can be taken out or clamped after the first station is welded, so that the utilization rate of equipment can be improved, and the welding yield can be improved. Compared with the traditional argon arc welding, the laser welding machine of the utility model adopts laser welding, does not contact products, does not need to use/replace tungsten needles, is more beautiful and smooth after welding products, has almost no heat influence, and does not need to be polished subsequently; in addition, the thin plate welded by argon arc welding with the thickness of 0.3mm or less than 0.3mm is easy to weld through, the rejection rate is high, the laser welding spot is small, the energy density is concentrated, the heat influence is small, and the welding yield is higher.

In this embodiment, the stainless steel double-layer bowl processing jig 4 includes an outer layer jig 41 connected to the top of the rotating disc 3 and an inner layer jig 42 rotatably connected to the output end of the pressing mechanism 8, and the outer layer jig 41 and the inner layer jig 42 are used for clamping a stainless steel double-layer bowl in a matching manner.

By adopting the technical scheme, when the stainless steel bowl clamping device is used, the outer layer fixture 41 is placed into the outer layer 13 of the stainless steel bowl, the inner layer fixture 42 is pressed downwards by starting the pressing mechanism 8 after the outer layer fixture 41 of the stainless steel bowl is placed into the outer layer fixture 13 of the stainless steel bowl in the same direction, so that the outer layer fixture 41 and the inner layer fixture 42 clamp the stainless steel double-layer bowl tightly, and the rotating disc 3 is driven to rotate synchronously.

In this embodiment, the pressing mechanism 8 includes a connecting seat 81 connected to the workbench 1, a pressing cylinder 82 connected to the top of the connecting seat 81, a sliding assembly connected to the side wall of the connecting seat 81, and a pressing member 83 connected to the sliding assembly, an output end of the pressing cylinder 82 penetrates through the connecting seat 81 and is connected to the pressing member 83, and the pressing member 83 is rotatably connected to the inner fixture 42.

By adopting the technical scheme, during use, the output end of the pressing cylinder 82 drives the pressing piece 83 to slide downwards so as to press the inner layer jig 42, the stainless steel double-layer bowl and the outer layer jig 41.

In this embodiment, a hollow connecting shaft 9 extends from the bottom of the pressing member 83, a rotating shaft 10 extending into the hollow connecting shaft 9 protrudes from the top of the inner fixture 42, a bearing 11 is sleeved on the rotating shaft 10, and the rotating shaft 10 is rotatably connected with the hollow connecting shaft 9 through the bearing 11; the sliding assembly comprises a first sliding rail 84 fixedly connected to the side wall of the connecting seat 81, and a first sliding block 85 slidably connected to the first sliding rail 84, and the pressing member 83 is fixedly connected to the first sliding block 85.

By adopting the technical scheme, the rotating shaft 10 is rotatably connected with the hollow connecting shaft 9 through the bearing 11, so that the rotating disc 3 can still drive the whole stainless steel double-layer bowl processing jig 4 to synchronously rotate after being compressed.

In this embodiment, the laser head adjusting mechanism 6 includes a Y-axis adjusting base 61 connected to the table 1, a Y-axis adjusting member 62 connected to a side wall of the Y-axis adjusting base 61, an X-axis adjusting base 63 connected to the Y-axis adjusting member 62, an X-axis adjusting member 64 connected to a side wall of the X-axis adjusting base 63, a θ -axis adjusting member 65 connected to a side wall of the X-axis adjusting member 64, and a laser head connecting block 66 connected to the θ -axis adjusting member 65, and the laser head connecting block 66 is connected to the laser head body 7.

By adopting the technical scheme, the distance and the angle between the laser head body 7 and the position to be welded are adjusted through the Y-axis adjusting component 62, the X-axis adjusting component 64 and the theta-axis adjusting component 65 so as to adapt to welding of products with different sizes.

In this embodiment, the Y-axis adjusting assembly 62 includes a second slide rail 621 fixedly connected to a side wall of the Y-axis adjusting base 61, a second slide block 622 slidably connected to the second slide rail 621, a first connecting block 623 connected to the second slide block 622, a first lead screw stepping motor 624 connected to a top of the Y-axis adjusting base 61, and a first lead screw nut 625 in threaded fit with an output end of the first lead screw stepping motor 624, where the first lead screw nut 625 and the X-axis adjusting base 63 are both fixedly connected to the first connecting block 623.

By adopting the above technical scheme, the first lead screw stepping motor 624 drives the first lead screw nut 625 to ascend and descend, and drives the first connecting block 623, the second sliding block 622 and the X-axis adjusting seat 63 to ascend and descend, so as to realize Y-axis direction adjustment.

In this embodiment, the X-axis adjusting assembly 64 includes a third slide rail 641 fixedly connected to a side wall of the X-axis adjusting base 63, a third slide block 642 slidably connected to the third slide rail 641, a second connection block 643 connected to the third slide block 642, a second lead screw stepping motor 644 connected to a top of the X-axis adjusting base 63, and a second lead screw nut 645 threadedly engaged with an output end of the second lead screw stepping motor 644, wherein the second lead screw nut 645 and the θ -axis adjusting assembly 65 are both fixedly connected to the second connection block 643.

By adopting the technical scheme, the second lead screw stepping motor 644 drives the second lead screw nut 645 to transversely move, so as to drive the second connecting block 643, the third sliding block 642 and the theta-axis adjusting component 65 to transversely move, so that the X-axis direction adjustment is realized.

In this embodiment, the θ -axis adjusting assembly 65 includes a hollow clamping sleeve 651 and a rotary adjusting seat 652 clamped in the middle of the hollow clamping sleeve 651, and the rotary adjusting seat 652 is fixedly connected to the laser head connecting block 66.

By adopting the technical scheme, the hollow clamping sleeve 651 is loosened, the rotating adjusting seat 652 is rotated to drive the laser head connecting block 66 to rotate, so that the rotating angles of the laser head connecting block 66 and the laser head body 7 are adjusted, then the hollow clamping sleeve 651 is fastened, the hollow clamping sleeve 651 clamps the rotating adjusting seat 652, and the rotating adjusting seat 652 is prevented from being loosened to influence the rotating angles of the laser head connecting block 66 and the laser head body 7.

In the embodiment, the speed reduction driving mechanism 2 includes a servo motor 21, a speed reducer 22 in transmission connection with an output end of the servo motor 21, and a hollow rotating shaft 23 connected with an output end of the speed reducer 22, and the hollow rotating shaft 23 is fixedly connected with the rotating disk 3.

By adopting the technical scheme, the hollow rotating shaft 23 drives the rotating disc 3 to stably rotate.

In this embodiment, the material pushing mechanism 5 includes an air cylinder fixing seat 51 connected to the bottom of the speed reducer 22, a material pushing air cylinder 52 connected to the air cylinder fixing seat 51, and a material pushing rod 53 connected to an output end of the material pushing air cylinder 52, where the material pushing rod 53 penetrates through the hollow rotating shaft 23 and the rotating disc 3 and abuts against the bottom of the stainless steel double-layer bowl processing jig 4.

By adopting the technical scheme, after welding is finished, the pressing mechanism 8 resets, the material pushing cylinder 52 pushes the material pushing rod 53 and pushes the stainless steel double-layer bowl to rise, and then the stainless steel double-layer bowl can be taken out and welding is finished.

The above-mentioned embodiment does the utility model discloses the implementation scheme of preferred, in addition, the utility model discloses can also realize by other modes, do not deviating from the utility model discloses any obvious replacement is all within the protection scope under the prerequisite of thinking.

Claims (10)

1. The utility model provides a double-deck bowl duplex position laser-beam welding machine of stainless steel which characterized in that: including the workstation, connect in the speed reduction actuating mechanism of the bottom of workstation, set up in the top of workstation and the rolling disc of being connected with speed reduction actuating mechanism's output, connect in the double-deck bowl processing tool of stainless steel at the top of rolling disc, run through speed reduction actuating mechanism and rolling disc in proper order and support and lean on the pushing equipment in the double-deck bowl processing tool bottom of stainless steel, connect in the laser head adjustment mechanism at the top of workstation, connect in the laser head body of laser head adjustment mechanism and connect in the hold-down mechanism at the top of workstation, the double-deck bowl processing tool of stainless steel is used for holding the double-deck bowl of stainless steel, the laser head body is used for the bowl mouth border of the double-deck bowl of laser welding stainless steel, hold-down mechanism and the double-deck bowl processing tool cooperation of stainless steel are used for pressing from both sides tight double-deck bowl of stainless steel.

2. The stainless steel double-layer bowl double-station laser welding machine according to claim 1, characterized in that: the stainless steel double-layer bowl processing jig comprises an outer layer jig connected to the top of the rotating disc and an inner layer jig rotatably connected to the output end of the pressing mechanism, and the outer layer jig and the inner layer jig are matched to be used for clamping and setting the stainless steel double-layer bowl.

3. The stainless steel double-layer bowl double-station laser welding machine according to claim 2, characterized in that: the pressing mechanism comprises a connecting seat connected to the workbench, a pressing air cylinder connected to the top of the connecting seat, a sliding assembly connected to the side wall of the connecting seat, and a pressing piece connected with the sliding assembly, wherein the output end of the pressing air cylinder penetrates through the connecting seat and is connected with the pressing piece, and the pressing piece is rotatably connected with the inner layer jig.

4. The stainless steel double-layer bowl double-station laser welding machine according to claim 3, characterized in that: a hollow connecting shaft extends from the bottom of the pressing piece, a rotating shaft extending into the hollow connecting shaft is convexly extended from the top of the inner-layer jig, a bearing is sleeved on the rotating shaft, and the rotating shaft is rotatably connected with the hollow connecting shaft through the bearing; the sliding assembly comprises a first sliding rail fixedly connected to the side wall of the connecting seat and a first sliding block connected with the first sliding rail in a sliding mode, and the pressing piece is fixedly connected with the first sliding block.

5. The stainless steel double-layer bowl double-station laser welding machine according to claim 1, characterized in that: laser head adjustment mechanism include with the Y axle that the workstation is connected is adjusted the seat, is adjusted the Y axle adjusting part that the lateral wall of seat is connected with the Y axle, is adjusted the seat with the X axle that Y axle adjusting part is connected, adjusts the X axle adjusting part that the lateral wall of seat is connected with the X axle, the theta axle adjusting part who is connected with the lateral wall of X axle adjusting part and the laser head connecting block who is connected with theta axle adjusting part, laser head connecting block and this body coupling of laser head.

6. The stainless steel double-layer bowl double-station laser welding machine according to claim 5, characterized in that: the Y-axis adjusting assembly comprises a second slide rail fixedly connected with the side wall of the Y-axis adjusting seat, a second slide block connected with the second slide rail in a sliding manner, a first connecting block connected with the second slide block, a first lead screw stepping motor connected with the top of the Y-axis adjusting seat, and a first lead screw nut in threaded fit with the output end of the first lead screw stepping motor, and the first lead screw nut and the X-axis adjusting seat are fixedly connected with the first connecting block.

7. The stainless steel double-layer bowl double-station laser welding machine according to claim 5, characterized in that: the X-axis adjusting assembly comprises a third slide rail fixedly connected with the side wall of the X-axis adjusting seat, a third slide block connected with the third slide rail in a sliding manner, a second connecting block connected with the third slide block, a second lead screw stepping motor connected with the top of the X-axis adjusting seat, and a second lead screw nut in threaded fit with the output end of the second lead screw stepping motor, and the second lead screw nut and the theta-axis adjusting assembly are fixedly connected with the second connecting block.

8. The stainless steel double-layer bowl double-station laser welding machine according to claim 5, characterized in that: the theta axis adjusting assembly comprises a hollow clamping sleeve and a rotating adjusting seat clamped in the middle of the hollow clamping sleeve, and the rotating adjusting seat is fixedly connected with the laser head connecting block.

9. The stainless steel double-layer bowl double-station laser welding machine according to claim 1, characterized in that: the speed reduction driving mechanism comprises a servo motor, a speed reducer in transmission connection with the output end of the servo motor, and a hollow rotating shaft connected with the output end of the speed reducer, and the hollow rotating shaft is fixedly connected with the rotating disc.

10. The double-layer bowl double-station laser welding machine for the stainless steel according to claim 9, characterized in that: the pushing mechanism comprises a cylinder fixing seat connected with the bottom of the speed reducer, a pushing cylinder connected with the cylinder fixing seat and a pushing rod connected with the output end of the pushing cylinder, and the pushing rod penetrates through the hollow rotating shaft and the rotating disc and is abutted to the bottom of the stainless steel double-layer bowl processing jig.

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