CN222919795U - Back plate double-head laser welding machine equipment - Google Patents

Abstract

The utility model relates to the technical field of laser welding, in particular to back plate double-head laser welding machine equipment which comprises a workbench, a linear module and a welding head, wherein the linear module comprises an X-axis linear module, a Y-axis linear module and a Z-axis linear module, the X-axis linear module is fixedly arranged on the workbench, the Z-axis linear module is slidably arranged on the X-axis linear module along an X axis, the Z-axis linear module can rotate along a horizontal plane relative to the X-axis linear module, the Y-axis linear module is slidably arranged on the Z-axis linear module along a Z axis, the welding head is slidably arranged on the Y-axis linear module along a Y axis, and the welding head can rotate along a vertical plane relative to the Y-axis linear module. The utility model solves the problem of the welding angle between the welding head and the welding seam and ensures the welding quality.

Description

Back plate double-head laser welding machine equipment

Technical Field

The utility model relates to the technical field of laser welding, in particular to a back plate double-head laser welding machine device.

Background

When the television backboard is processed, the front stage is formed by punching through a plurality of punching machines, the spliced parts (two corner positions) at the top of the backboard after punching are required to be welded, so that the television backboard is integrated, most of the existing welding modes adopt robots to weld, one corner welding is finished firstly, and then the other corner welding is finished, but the welding cost of the robots is high, the occupied position space is large, the welding is difficult to adapt to the welding of backboard with different specifications, and the welding efficiency is low.

In order to solve the above-mentioned problems, a laser welder dedicated to a television backboard is disclosed in the prior art, but its welding head is horizontally arranged and parallel to one side of the backboard, so that the welding quality cannot be ensured due to the welding angle of the welding head and the welding seam.

Disclosure of utility model

Aiming at the defects existing in the prior art, the embodiment of the utility model aims to provide a back plate double-head laser welding machine device so as to solve the problem of a welding angle between a welding head and a welding line and ensure welding quality.

In order to achieve the above object, the embodiment of the present utility model provides the following technical solutions:

The back plate double-head laser welding machine comprises a workbench, a linear module and a welding head, wherein the linear module comprises an X-axis linear module, a Y-axis linear module and a Z-axis linear module, the X-axis linear module is fixedly arranged on the workbench, the Z-axis linear module is slidably arranged on the X-axis linear module along an X axis, the Z-axis linear module can rotate along a horizontal plane relative to the X-axis linear module, the Y-axis linear module is slidably arranged on the Z-axis linear module along a Z axis, the welding head is slidably arranged on the Y-axis linear module along a Y axis, and the welding head can rotate along a vertical plane relative to the Y-axis linear module.

Optionally, the adapter plate capable of sliding along the X axis is arranged on the X axis linear die, a fixing frame is arranged at the bottom of the Z axis linear die set, and the fixing frame is rotatably arranged on the adapter plate of the X axis linear die set.

Optionally, the adapter plate is a rectangular sliding block, the fixing frame is a circular plate, a plurality of sections of arc grooves are formed in the fixing frame, and the adapter plate is connected to the arc grooves penetrating through the fixing frame by using screws.

Optionally, two groups of straight line modules and two groups of welding heads are arranged on the workbench, the straight line modules comprise a first straight line module and a second straight line module, and the welding heads comprise a first welding head arranged on the first straight line module and a second welding head arranged on the second straight line module.

Optionally, the slide mechanism of installation work piece backplate is installed on the workstation, slide mechanism is including first X axle slide and the second X axle slide that can follow the X axle and remove, install on the first X axle slide and follow Y axle gliding first Y axle slide and second Y axle slide, install on the second X axle slide and follow Y axle gliding third Y axle slide and fourth Y axle slide.

Optionally, a clamping mechanism and a positioning seat are installed on the first Y-axis sliding plate, a convex plate is arranged on the positioning seat, a groove is formed in the middle of the convex plate, the clamping mechanism comprises an air cylinder, a pressing plate and a supporting rod, the middle of the pressing plate is rotatably installed on the supporting rod, the outer end of the pressing plate is installed on a piston rod of the air cylinder, the inner end of the pressing plate penetrates through the groove and can be in compression joint with a workpiece backboard, and a first clamping mechanism and a second clamping mechanism which are perpendicular to each other and a first positioning seat and a second positioning seat which are perpendicular to each other are installed on the first Y-axis sliding plate.

Optionally, a pushing mechanism and a third positioning seat are installed on the second Y-axis sliding plate, the pushing mechanism is used for pushing the workpiece backboard to move and comprises an air cylinder and a pushing plate, the second Y-axis sliding plate is provided with a first pushing mechanism, the pushing plate of the first pushing mechanism is opposite to the first positioning seat, and the third positioning seat is parallel to the second positioning seat.

Optionally, a second pushing mechanism, a fourth positioning seat and a third clamping mechanism are installed on the third Y-axis sliding plate, the second pushing mechanism is opposite to the second positioning seat, the fourth positioning seat is parallel to the first positioning seat, and the third clamping mechanism is located on the back side of the fourth positioning seat.

Optionally, a third pushing mechanism and a fourth pushing mechanism are arranged on the fourth Y-axis sliding plate, the third pushing mechanism is opposite to the fourth positioning seat, and the fourth pushing mechanism is opposite to the third positioning seat.

Optionally, the welding machine equipment further comprises a control monitoring system and a water cooling machine, wherein the control monitoring system is installed on the front end table top of the workbench, and the water cooling machine is installed on one side of the workbench.

One or more technical solutions provided in the embodiments of the present utility model at least have the following technical effects or advantages:

The workbench of the welding machine equipment is provided with the linear modules for installing the welding head, and the accurate positioning of the welding head in space is realized through the cooperative work of the three groups of linear modules. And wherein the Z-axis linear module can rotate in the horizontal plane relative to the X-axis linear module, and the welding head can rotate in the vertical plane relative to the Y-axis linear module, so that when the workpiece back plate is welded, the welding head can be arranged along an extension line of the splicing direction of the workpiece back plate instead of being parallel to one edge of the workpiece back plate, and simultaneously, the welding head and the horizontal plane form a preset angle through the vertical arrangement of the welding head, so that the welding head and the corner weld joint form an optimal welding angle through the rotation of the Y-axis linear module and the welding head, and the welding quality is ensured.

Additional aspects of the utility model 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 utility model.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model.

FIG. 1 is a schematic view of an embodiment of a welder apparatus;

FIG. 2 is a schematic diagram of a television back panel according to an embodiment of the present utility model;

FIG. 3 is a schematic diagram of a linear module according to an embodiment of the present utility model;

FIG. 4 is a schematic view of a slide-on-table mechanism according to an embodiment of the present utility model;

FIG. 5 is a schematic view of a first Y-axis skateboard provided by an embodiment of the utility model;

FIG. 6 is a schematic view of a second Y-axis sled according to an embodiment of the present utility model;

FIG. 7 is a schematic view of a third Y-axis sled according to an embodiment of the present utility model;

FIG. 8 is a schematic view of a fourth Y-axis sled according to an embodiment of the present utility model;

In the figure, 1, a workbench; 2, a first linear module; 3, a second linear module; 4, a first welding head, 5, a second welding head, 6, a first X-axis sliding plate, 7, a second X-axis sliding plate, 8, a first Y-axis sliding plate, 9, a second Y-axis sliding plate, 10, a third Y-axis sliding plate, 11, a fourth Y-axis sliding plate, 12, a control monitoring system, 13, a water cooling machine, 100, a workpiece back plate, 101, a first X-axis guide rail, 102, a second X-axis guide rail, 103, a second X-axis guide rail, 104, a first X-axis guide rail, 201, an X-axis linear module, 2011, an adapter plate, 202, a Z-axis linear module, 2021, a fixing frame, 203, a Y-axis linear module, 2031, a rotating wheel, 401, a clamping seat, 402, a connecting sleeve, 601, a first Y-axis guide rail, 602, a first Y-axis guide rail, 603, a second Y-axis guide rail, 604, a lead screw locking seat, 701, a second Y-axis guide rail, 702, a third Y-axis guide rail, 703, a fourth Y-axis, 801, a first clamping mechanism, 802, a second clamping mechanism, a third positioning seat 803, a fourth positioning seat, a third positioning seat, a fourth positioning mechanism, a driving seat 803, a third positioning seat, a driving mechanism, a driving seat, a 1001, a third positioning seat, a 1001;

the mutual spacing or dimensions are exaggerated for the purpose of showing the positions of the various parts, and the schematic illustrations are used for illustration only.

Detailed Description

It should be noted that the following detailed description is illustrative and is intended to provide further explanation of the utility model. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. Furthermore, it will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, steps, operations, devices, mechanisms, and/or combinations thereof.

Term interpretation:

A linear module, also known as a linear guide system or linear motion module, is a mechanical component for effecting linear motion. The linear motion control device is widely applied to the fields of automation equipment, robots, conveying systems, precision positioning platforms and the like so as to realize precisely controlled linear motion. The linear module comprises a guide rail, a slide block, a bearing, a driving element and the like, wherein the driving element transmits power to the slide block through a connecting piece, so that the slide block moves linearly along the guide rail. The sliding block is internally provided with the rolling elements, so that low-friction and high-precision linear motion can be realized.

As shown in fig. 1 and 2, an embodiment of the present utility model provides a back plate dual-head laser welding machine device, which includes a workbench 1, a linear module and a welding head, wherein the linear module includes an X-axis linear module 201, a Y-axis linear module 203 and a Z-axis linear module 202;

The X-axis linear module 201 is fixedly installed on the workbench 1, the Z-axis linear module 202 is installed on the X-axis linear module 201 in a sliding mode along an X axis, the Z-axis linear module 202 can rotate along a horizontal plane relative to the X-axis linear module 201, the Y-axis linear module 203 is installed on the Z-axis linear module 202 in a sliding mode along a Z axis, the welding head is installed on the Y-axis linear module 203 in a sliding mode along a Y axis, and the welding head can rotate along a vertical plane relative to the Y-axis linear module 203.

The workbench 1 of the welding machine equipment is provided with the linear modules for installing the welding head, and the accurate positioning of the welding head in space is realized through the cooperative work of the three groups of linear modules. Moreover, the Z-axis linear module 202 may rotate in a horizontal plane relative to the X-axis linear module 201, and the welding head may rotate in a vertical plane relative to the Y-axis linear module 203, so that when the workpiece back plate 100 is welded, the welding head may be disposed along an extension line of a splicing direction of the workpiece back plate 100 instead of being parallel to one side of the workpiece back plate 100, and simultaneously, the welding head may be disposed at a predetermined angle with respect to the horizontal plane by vertical arrangement of the welding head, so that the welding head and the corner weld may form an optimal welding angle by rotation of the Y-axis linear module 203 and the welding head, thereby ensuring welding quality.

As shown in fig. 3, in the present embodiment, an adapter plate 2011 capable of sliding along the X axis is disposed on the X axis linear module 201, and the adapter plate 2011 is generally designed as a rectangular slider to realize smooth sliding. The bottom of the Z-axis linear module 202 is provided with a fixing frame 2021, the fixing frame 2021 is designed as a circular plate, and a plurality of segments of arc grooves are arranged on the fixing frame and are used for being connected with the adapter plate 2011, and fixing is usually achieved through screws. The above structure may be adopted as the rotating structure of the welding head, and it is understood that the welding head may be fixed on the connecting shaft sleeve 402, and the connecting shaft sleeve 402 may be rotatably mounted on the clamping seat 401, so long as the welding head can rotate in a vertical plane.

As shown in fig. 1 and 2, in this embodiment, two sets of linear modules and two sets of welding heads are disposed on the workbench 1, so as to realize the function of simultaneous welding of the two heads. The first and second linear modules 2 and 3 are mounted on the same side of the table 1, and the first and second bonding heads 4 and 5 are mounted on the corresponding linear modules, respectively. The first linear module 2 and the second linear module 3 are designed by considering symmetry of the equipment and coordination of operation so as to realize high efficiency and consistency of double-head welding. The first bonding head 4 and the second bonding head 5 are mounted to ensure that they operate independently and cooperate to accommodate the bonding requirements of back plates of different shapes and sizes.

As shown in fig. 4, in the present embodiment, a slide plate mechanism for mounting the work back plate 100 is mounted on the table 1. The slide mechanism includes a first X-axis slide 6 and a second X-axis slide 7 movable along the X-axis, and is guided by a first X-axis guide rail 101 and a second X-axis guide rail 102, and driven by a first X-axis screw 104 and a second X-axis screw 103. Also included are a first Y-axis slide 8, a second Y-axis slide 9, a third Y-axis slide 10 and a fourth Y-axis slide 11 that are capable of sliding along the Y-axis. Is guided by the first Y-axis guide rail 601 and the second Y-axis guide rail 701, is driven by the first Y-axis screw 602, the second Y-axis screw 603, the third Y-axis screw 702 and the fourth Y-axis screw 703, and is locked by the screw locking seat 604.

In this embodiment, the clamping mechanism, the positioning seat and the pushing mechanism are similar in structure, and only the directions are different. The clamping mechanism comprises an air cylinder, a pressing plate and a supporting rod, wherein the middle of the pressing plate is rotatably installed on the supporting rod, the outer end of the pressing plate is installed on a piston rod of the air cylinder, and the inner end of the pressing plate penetrates through a groove in the middle of a convex plate on the positioning seat and can be pressed on the workpiece backboard 100. The design of the clamping mechanism takes into account the stability of the fixing of the workpiece back plate 100, and the selection of the air cylinder is required to meet the requirement of the clamping force. The projection and recess designs on the positioning block ensure accurate positioning of the workpiece back plate 100 and efficient operation of the clamping mechanism. The pushing mechanism is used for pushing the workpiece back plate 100 to move, and comprises an air cylinder and a pushing plate, and the pushing mechanism is designed to take the size and the direction of the pushing force into consideration so as to adapt to the moving requirement of the workpiece back plate 100.

As shown in fig. 5, in the present embodiment, a first clamping mechanism 801 and a second clamping mechanism 802, which are perpendicular to each other, and a first positioning seat 803 and a second positioning seat 804, which are perpendicular to each other, are mounted on the first Y-axis slide plate 8. This design allows the workpiece back plate 100 to be clamped and positioned in both the X-axis and Y-axis directions, improving the accuracy and stability of the weld. Wherein the vertical arrangement of the first clamping mechanism 801 and the second clamping mechanism 802 provides clamping forces in the X-axis and Y-axis directions, ensuring stability of the workpiece back plate 100 during welding. The vertical arrangement of the first and second positioning seats 803, 804 ensures accurate positioning of the workpiece back plate 100 in both directions.

As shown in fig. 6, in the present embodiment, a first pushing mechanism 901 and a third positioning seat 902 are mounted on the second Y-axis slide plate 9. The push plate of the first pushing mechanism 901 is opposite to the first positioning seat 803, and the third positioning seat 902 is parallel to the second positioning seat 804, so as to ensure the two-point positioning precision of the workpiece backboard 100 in the moving process.

As shown in fig. 7, in the present embodiment, the second pushing mechanism 1002, the fourth positioning block 1003, and the third clamping mechanism 1001 are mounted on the third Y-axis sled 10. The second pushing mechanism 1002 is opposite to the second positioning seat 804, the fourth positioning seat 1003 is parallel to the first positioning seat 803, and the third clamping mechanism 1001 is located at the back side of the fourth positioning seat 1003.

The second pushing mechanism 1002 is designed to cooperate with the second positioning seat 804 to push and position the workpiece back plate 100. The fourth positioning seat 1003 is designed to be parallel to the first positioning seat 803 so as to maintain the positioning consistency of the workpiece back plate 100 during the moving process.

As shown in fig. 8, in the present embodiment, a third pushing mechanism 1101 and a fourth pushing mechanism 1102 are provided on the fourth Y-axis slide plate 11. The third pushing mechanism 1101 is opposite to the fourth positioning seat 1003, and the fourth pushing mechanism 1102 is opposite to the third positioning seat 902. The third and fourth pushing mechanisms 1101, 1102 are designed to allow for their cooperation with corresponding positioning seats to achieve efficient pushing and accurate positioning of the workpiece back plate 100.

In this embodiment, the welder apparatus further includes a control monitoring system 12 and a water chiller 13. The control monitoring system 12 is installed on the front end table top of the workbench 1 and is used for monitoring the welding effect and the equipment state in real time. A water cooler 13 is installed at one side of the table 1 for cooling the welding head and related parts, ensuring the stability of the welding process and safe operation of the apparatus.

In summary, the back plate double-head laser welding machine of the embodiment comprises a workbench 1, two sets of laser welding heads, two sets of XYZ linear modules, two sets of X-axis T-shaped screw rod adjusting slide plate mechanisms, four sets of Y-axis T-shaped screw rod adjusting slide plate mechanisms, four sets of clamping and positioning mechanisms respectively arranged on the Y-axis adjusting slide plates, a control and monitoring system 12 and a water cooling machine 13, so that the problems of high welding cost, large occupied position space, difficulty in adapting to the welding of back plates with different specifications and low welding efficiency due to the adoption of robots are improved, and the welding process can be monitored visually.

The using process of the welding machine equipment comprises the following steps:

When the back plate double-head laser welding machine operates, according to the specification and the size of the length direction of the television back plate, the hand wheels arranged on the first X-axis screw 104 and the second X-axis screw 103 are manually rotated, the nuts on the T-shaped screws are driven to rotate, the first X-axis sliding plate 6 and the second X-axis sliding plate 7 connected to the T-shaped nuts are driven to move leftwards or rightwards along the X-axis direction, after the spacing between the positioning seats on the second Y-axis sliding plate 9 and the fourth Y-axis sliding plate 11 meets the workpiece on-line positioning gap, the locking seats on the hand wheels of the first X-axis screw 104 and the second X-axis screw 103 are respectively locked, and deviation of the spacing between the positioning seats on the second Y-axis sliding plate 9 and the fourth Y-axis sliding plate 11 is avoided.

The hand wheels arranged on the first Y-axis lead screw 602 and the third Y-axis lead screw 702 are manually rotated, nuts on the first Y-axis lead screw 602 and the third Y-axis lead screw 702 are driven to rotate, the first Y-axis sliding plate 8 and the third Y-axis sliding plate 10 are driven to move forwards or backwards along the Y-axis direction, the positioning seats arranged on the first Y-axis sliding plate 8 and the third Y-axis sliding plate 10 are guaranteed to be coplanar and parallel to the first X-axis guide rail 101, and after adjustment is completed, locking seats on the hand wheel sides of the first Y-axis lead screw 602 and the third Y-axis lead screw 702 are respectively locked, so that deviation of the spacing between the positioning seats on the first Y-axis sliding plate 8 and the third Y-axis sliding plate 10 is avoided.

According to the width dimension of the television backboard, the hand wheels arranged on the second Y-axis lead screw 603 and the fourth Y-axis lead screw 703 are manually rotated to drive nuts on the second Y-axis lead screw 603 and the fourth Y-axis lead screw 703 to rotate to drive the second Y-axis sliding plate 9 and the fourth Y-axis sliding plate 11 to move forwards or backwards along the Y-axis direction, the spacing between the positioning seats arranged on the second Y-axis sliding plate 9 and the fourth Y-axis sliding plate 11 of the Y-axis sliding plate is adjusted to meet the line-feeding positioning gap of a workpiece, the positioning seats arranged on the second Y-axis sliding plate 9 and the fourth Y-axis sliding plate 11 are coplanar and parallel to the first X-axis guide rail 101 of the linear guide rail, and after adjustment, the screw locking seats 604 on the hand wheels of the second Y-axis lead screw 603 and the fourth Y-axis lead screw are respectively locked to avoid deviation, after adjustment, the workpiece can be rapidly positioned and locked, the workpiece positioning consistency is ensured, and the product quality stability and the yield are improved.

After the tool positioning adjustment is completed, when the equipment is operated, the moving manipulator moves the workpiece to the position above the tool positioning of the back plate double-head laser welding machine, and after the workpiece is put down, the moving manipulator resets.

The first pushing mechanism 901 and the third pushing mechanism 1101 which are arranged on the second Y-axis sliding plate 9 and the fourth Y-axis sliding plate 11 push the workpiece to the positioning seat side of the first Y-axis sliding plate 8 and the third Y-axis sliding plate 10 at the same time, and the second pushing mechanism 1002 and the fourth pushing mechanism 1102 which are arranged on the third Y-axis sliding plate 10 and the fourth Y-axis sliding plate 11 push the workpiece to the welding position of the positioning seat side of the first Y-axis sliding plate 8 and the third Y-axis sliding plate 10 to finish workpiece positioning.

The first clamping mechanism 801, the second clamping mechanism 802, and the third clamping mechanism 1001 mounted on the first Y-axis slide 8 and the third Y-axis slide 10 synchronously perform workpiece clamping.

According to the positioning position of the motor backboard after the adjustment is finished, the installation and connection angles of the fixing frame 2021 of the Z-axis linear module 202 and the adapter plate 2011 connected to the sliding block of the X-axis linear module 201 are manually adjusted respectively, so that the angle between the welding head and the welding position of the workpiece is ensured, and the phenomenon that the welding head and the workpiece have too large or too small included angle during welding to cause overselding or lack of welding on two sides of a welding line is avoided.

The runner 2031 of the Y-axis linear module 203 is manually rotated, the gap between the welding head and the workpiece is adjusted within the laser light emitting range of the welding head, the welding head can be adjusted along the Z axis at the workpiece clamping seat 401 of the Y-axis linear module 203, the welding connecting shaft sleeve 402 is adjusted to rotate upwards or downwards along the Z axis, the welding head is locked and clamped after the angle of the welding head is adjusted, the welding angle between the welding head and the workpiece is ensured, and the welding quality of a welding seam is ensured.

The welding operation of the workpiece is synchronously completed by the two sets of welding heads arranged on two sides of the workpiece after the workpiece is positioned, and the welding process synchronously displays the welding seam forming process on the monitoring display screen.

While the foregoing description of the embodiments of the present utility model has been presented in conjunction with the drawings, it should be understood that it is not intended to limit the scope of the utility model, but rather, it is intended to cover all modifications or variations within the scope of the utility model as defined by the claims of the present utility model.

Claims (10)

1. The back plate double-head laser welding machine equipment is characterized by comprising a workbench, a linear module and a welding head, wherein the linear module comprises an X-axis linear module, a Y-axis linear module and a Z-axis linear module;

The X-axis linear module is fixedly mounted on the workbench, the Z-axis linear module is mounted on the X-axis linear module in a sliding manner along an X axis, the Z-axis linear module can rotate along a horizontal plane relative to the X-axis linear module, the Y-axis linear module is mounted on the Z-axis linear module in a sliding manner along a Z axis, the welding head is mounted on the Y-axis linear module in a sliding manner along a Y axis, and the welding head can rotate along a vertical plane relative to the Y-axis linear module.

2. The back plate double-head laser welding machine equipment according to claim 1, wherein the adapter plate capable of sliding along the X axis is arranged on the X axis linear die, a fixing frame is arranged at the bottom of the Z axis linear die set, and the fixing frame is rotatably arranged on the adapter plate of the X axis linear die set.

3. The back plate double-head laser welding machine equipment according to claim 2, wherein the adapter plate is a rectangular sliding block, the fixing frame is a circular plate, a plurality of sections of arc grooves are formed in the fixing frame, and the arc grooves penetrating through the fixing frame through screws are connected to the adapter plate.

4. The backboard dual-head laser welder apparatus of claim 1, wherein two sets of linear modules and two sets of welding heads are provided on the work table, the linear modules including a first linear module and a second linear module, the welding heads including a first welding head mounted on the first linear module and a second welding head mounted on the second linear module.

5. The back plate dual head laser welder apparatus of claim 1, wherein the platen has mounted thereon a slide plate mechanism for mounting the workpiece back plate, the slide plate mechanism comprising a first X-axis slide plate and a second X-axis slide plate movable along the X-axis, the first X-axis slide plate having mounted thereon a first Y-axis slide plate and a second Y-axis slide plate slidable along the Y-axis, the second X-axis slide plate having mounted thereon a third Y-axis slide plate and a fourth Y-axis slide plate slidable along the Y-axis.

6. The back plate double-head laser welding machine equipment according to claim 5, wherein the first Y-axis sliding plate is provided with a clamping mechanism and a positioning seat, the positioning seat is provided with a convex plate, the middle of the convex plate is provided with a groove, the clamping mechanism comprises an air cylinder, a pressing plate and a supporting rod, the middle of the pressing plate is rotatably arranged on the supporting rod, the outer end of the pressing plate is arranged on a piston rod of the air cylinder, the inner end of the pressing plate penetrates through the groove and can be pressed on a back plate of a workpiece, and the first Y-axis sliding plate is provided with a first clamping mechanism and a second clamping mechanism which are perpendicular to each other, and the first positioning seat and the second positioning seat which are perpendicular to each other.

7. The back plate double-head laser welding machine equipment according to claim 6, wherein the second Y-axis sliding plate is provided with a pushing mechanism and a third positioning seat, the pushing mechanism is used for pushing the back plate of the workpiece to move and comprises a cylinder and a pushing plate, the second Y-axis sliding plate is provided with a first pushing mechanism, the pushing plate of the first pushing mechanism is opposite to the first positioning seat, and the third positioning seat is parallel to the second positioning seat.

8. The back plate dual-head laser welder apparatus of claim 7, wherein a second pushing mechanism, a fourth positioning seat and a third clamping mechanism are mounted on the third Y-axis slide plate, the second pushing mechanism is opposite to the second positioning seat, the fourth positioning seat is parallel to the first positioning seat, and the third clamping mechanism is located at a back side of the fourth positioning seat.

9. The back plate dual-head laser welder apparatus of claim 8, wherein a third pushing mechanism and a fourth pushing mechanism are disposed on the fourth Y-axis sled, the third pushing mechanism being opposite the fourth positioning seat, the fourth pushing mechanism being opposite the third positioning seat.

10. The back plate dual-head laser welder apparatus of claim 1, further comprising a control monitoring system mounted on the front-end table top of the work table and a water cooler mounted on one side of the work table.