阅读说明：本技术 一种风管用数控旋转钻铆胶设备 (Numerical control rotary drill riveting equipment for air pipe ) 是由 邱云幸 于 2021-08-24 设计创作，主要内容包括：本发明涉及风管加工装置技术领域,特别地,涉及一种风管用数控旋转钻铆胶设备包括机架、X轴方向、Y轴方向、Z轴方向、用于钻取铆钉孔的第一钻孔装置,以及铆钉枪,所述设备还包括用于沿Y轴方向输送工件的输送线、设于机架上的第一线性模组,以及两分别设于第一线性模组上且分别位于输送线两侧的双轴直线模组,所述第一线性模组用于驱动所述双轴直线模组沿X轴方向移动；所述双轴直线模组上设有安装座,所述双轴直线模组用于驱动安装座沿Y轴方向、Z轴方向移动；所述第一钻孔装置和铆钉枪设于安装座上。本发明采用机械代替传统的人工方式,有助于提高效率,而且可以对工件的双面进行加工。(The invention relates to the technical field of air pipe processing devices, in particular to a numerical control rotary drilling and riveting device for an air pipe, which comprises a rack, an X-axis direction, a Y-axis direction, a Z-axis direction, a first drilling device for drilling a rivet hole, a rivet gun, a conveying line for conveying a workpiece along the Y-axis direction, a first linear module arranged on the rack, and two double-axis linear modules which are respectively arranged on the first linear module and are respectively positioned on two sides of the conveying line, wherein the first linear module is used for driving the double-axis linear module to move along the X-axis direction; the double-shaft linear module is provided with a mounting seat and is used for driving the mounting seat to move along the Y-axis direction and the Z-axis direction; the first drilling device and the rivet gun are arranged on the mounting base. The invention adopts machinery to replace the traditional manual mode, is beneficial to improving the efficiency and can process the two sides of the workpiece.)

1. The numerical control rotary drilling and riveting equipment for the air pipe comprises a rack, an X-axis direction, a Y-axis direction, a Z-axis direction, a first drilling device for drilling a rivet hole and a rivet gun, and is characterized by further comprising a conveying line for conveying a workpiece along the Y-axis direction, a first linear module arranged on the rack, and two double-axis linear modules which are respectively arranged on the first linear module and are respectively positioned on two sides of the conveying line, wherein the first linear module is used for driving the double-axis linear module to move along the X-axis direction; the double-shaft linear module is provided with a mounting seat and is used for driving the mounting seat to move along the Y-axis direction and the Z-axis direction; the first drilling device and the rivet gun are arranged on the mounting seat; the equipment also comprises a material pressing mechanism which is moved along with the double-shaft linear module and is used for pressing the upper end of the workpiece, and two side pressing mechanisms which are arranged on two sides of the conveying line and are used for abutting against the side wall of the workpiece.

2. The numerical control rotary drilling and riveting equipment for the air pipes according to claim 1, wherein the mounting seat is further provided with a first scanning device for horizontally scanning the workpiece along the Y-axis direction and a second scanning device for vertically scanning the workpiece along the Z-axis direction.

3. The numerical control rotary drilling and riveting equipment for the air pipes according to claim 1 or 2, wherein the first linear modules comprise two groups, the two first linear modules are arranged side by side at intervals, and the double-shaft linear modules are arranged on the two first linear modules.

4. The numerical control rotary drilling and riveting device for the air pipes as claimed in claim 1, wherein the pressing mechanism comprises a first pressing bar for pressing the upper end of the workpiece, and a first driving piece for driving the first pressing bar to move along the Z-axis direction.

5. The numerical control rotary drilling and riveting device for the air pipes as claimed in claim 4, wherein the lateral pressing mechanism comprises a second pressing bar for pressing against the side wall of the workpiece, and a second driving piece for driving the second pressing bar to move along the X-axis direction.

6. The numerical control rotary drilling and riveting equipment for the air pipes according to claim 1, wherein the first driving part and/or the second driving part is an air cylinder or a hydraulic cylinder.

7. The numerical control rotary drilling and riveting equipment for the air pipes according to claim 1, wherein the conveying line is a roller line.

8. The numerical control rotary drilling and riveting device for the air pipes as claimed in claim 1, wherein the working ends of the first drilling device and the riveting gun are located on the same horizontal line along the Y-axis direction.

9. The numerical control rotary drilling and riveting equipment for the air pipes according to claim 1/2/4/5/6/7/8, wherein a glue gun for gluing a workpiece is arranged on the mounting seat; and/or a second drilling device for drilling a reinforcing hole in the workpiece is arranged on the mounting seat.

10. The numerical control rotary drilling and riveting equipment for the air pipes as claimed in claim 1, wherein the conveying line comprises a first roller line and a second roller line, the first roller line is used for conveying workpieces along the Y-axis direction, and a circular opening is formed in the middle of the first roller line; the second roll line is arranged in the opening and is rotationally arranged, the second roll line is further connected with a driving mechanism, and the driving mechanism drives the second roll line to integrally rotate around the axis direction of the circular opening.

Technical Field

The invention relates to the technical field of air pipe processing devices, in particular to a numerical control rotary drilling and riveting rubber device for an air pipe.

Background

During the manufacture of the air duct, flanges are usually mounted at two ends of the air duct, and the flanges are mainly fixed, namely riveted, by rivets.

The riveting of the air pipe generally comprises the steps of drilling and rivet pulling, namely, firstly, a rivet hole for a rivet to pass through is drilled on the air pipe and the flange by using an electric drill, and then, a rivet gun is used for rivet pulling operation in the rivet hole, so that the riveting of the air pipe is realized. However, at present, the above two steps are mainly performed manually, which is not only labor-intensive, but also very inefficient, and thus needs to be improved.

Disclosure of Invention

In view of the above, the invention aims to provide a numerical control rotary drilling and riveting glue device for an air pipe.

In order to solve the technical problems, the technical scheme of the invention is as follows:

a numerical control rotary drilling and riveting device for air pipes comprises a rack, an X-axis direction, a Y-axis direction, a Z-axis direction, a first drilling device for drilling rivet holes, a rivet gun, a conveying line for conveying workpieces along the Y-axis direction, a first linear module arranged on the rack, and two double-axis linear modules which are respectively arranged on the first linear module and are respectively positioned on two sides of the conveying line, wherein the first linear module is used for driving the double-axis linear module to move along the X-axis direction; the double-shaft linear module is provided with a mounting seat and is used for driving the mounting seat to move along the Y-axis direction and the Z-axis direction; the first drilling device and the rivet gun are arranged on the mounting seat; the equipment also comprises a material pressing mechanism which moves along with the double-shaft linear module and is used for pressing the workpiece, and two side pressing mechanisms which are arranged on two sides of the conveying line and are used for abutting against the side wall of the workpiece.

The advantage of this scheme of adoption lies in:

at first, in this scheme, through setting up biax straight line module to utilize the mount pad to install riveter and first drilling equipment, so drive first drilling equipment and riveter by biax straight line module and realize Y axle, Z axle direction motion, so alright realize drilling the flange at work piece both ends, rivet the operation, so than traditional manual work, can reduce intensity of labour undoubtedly, also improved work efficiency greatly.

Secondly, in this scheme, be equipped with two biax straight line modules at the transfer chain to all install first drilling equipment and riveter through the mount pad on every biax straight line module, so can bore the operation of riveting to the both sides of work piece simultaneously, further improve work efficiency.

And because the two biaxial linear modules are driven by the first linear module, the distance between the two biaxial linear modules can be adjusted to be matched with the width of the workpiece, so that the two biaxial linear modules can be suitable for processing workpieces with various width sizes.

Finally, the scheme is provided with a material pressing mechanism for pressing the upper end of the workpiece and two side pressing mechanisms which are respectively arranged on two sides of the conveying line and used for pressing the side walls of the workpiece, wherein the side pressing mechanisms can press two sides of the workpiece to enable the workpiece to be clamped between the pressing mechanisms on the two sides, the stability of the workpiece is guaranteed, meanwhile, the material pressing mechanism can press the upper end of the workpiece, the clamping stability of the workpiece is further improved, the material pressing mechanism is arranged on the double-shaft linear module and can move along with the double-shaft linear module integrally, and therefore when the double-shaft linear module moves and adjusts, the material pressing mechanism also moves along with the double-shaft linear module, and the material pressing mechanism can be enabled to adapt to the workpiece and is located above the workpiece.

Furthermore, a first scanning device for horizontally scanning the workpiece along the Y-axis direction and a second scanning device for vertically scanning the workpiece along the Z-axis direction are arranged on the mounting seat

Furthermore, first linear module includes two sets ofly, and two first linear module sets up side by side at the interval, biax straight line module is located on two first linear modules.

Furthermore, the pressing mechanism comprises a first pressing strip used for pressing the upper end of the workpiece, and a first driving piece used for driving the first pressing strip to move along the Z-axis direction.

Furthermore, the side pressing mechanism comprises a second pressing strip used for pressing against the side wall of the workpiece, and a second driving piece used for driving the second pressing strip to move along the X-axis direction.

Further, the first driving member and/or the second driving member is/are a cylinder or a hydraulic cylinder.

Further, the conveying line is a roller line.

Furthermore, the working ends of the first drilling device and the rivet gun are located on the same horizontal line along the Y-axis direction.

Furthermore, a glue gun for gluing the workpiece is arranged on the mounting seat; and/or a second drilling device for drilling a reinforcing hole in the workpiece is arranged on the mounting seat.

Further, the conveying line comprises a first roller line and a second roller line, the first roller line is used for conveying the workpiece along the Y-axis direction, and a circular opening is formed in the middle of the first roller line; the second roll line is arranged in the opening and is rotationally arranged, the second roll line is further connected with a driving mechanism, and the driving mechanism drives the second roll line to integrally rotate around the axis direction of the circular opening.

Other advantages and effects of the invention are specifically set forth in the detailed description section.

Drawings

FIG. 1 is a schematic view of the structure of the present invention in a front view;

FIG. 2 is a side view of the present invention;

FIG. 3 is a schematic view of a workpiece structure;

fig. 4 is a schematic top view of the conveyor line.

Detailed Description

The following detailed description of the embodiments of the present invention is provided in order to make the technical solution of the present invention easier to understand and understand.

Example (b):

as shown in fig. 1, the present embodiment provides a numerical control rotary drilling and riveting device for an air duct, which includes a frame 2, an X-axis direction, a Y-axis direction, a Z-axis direction, a first drilling device 11 for drilling a rivet hole 12, and a rivet gun; the X-axis direction, the Y-axis direction, and the Z-axis direction herein do not refer to a physically existing shaft body, but refer to directions only, and specific X-axis direction, Y-axis direction, and Z-axis direction are shown in fig. 1 and 2, and two of the X-axis direction, the Y-axis direction, and the Z-axis direction are perpendicular to each other.

The equipment further comprises a conveying line 21 used for conveying workpieces along the Y-axis direction, a first linear module 3 arranged on the rack 2, and two double-shaft linear modules which are respectively arranged on the first linear module 3 and are respectively positioned on two sides of the conveying line 21. Be equipped with mount pad 6 on the biax straight line module, the biax straight line module is used for driving mount pad 6 and removes along Y axle direction, Z axle direction.

Biax straight line module specifically includes second straight line module 4 in this embodiment, and third straight line module 5, wherein first linear module 3, second straight line module 4, and third straight line module 5, all can adopt current rack and pinion servo straight line module, also generally call rack and pinion linear module, this module mainly includes the slide rail, sliding connection is at the slip table on the slide rail, and the servo motor of drive slip table along slide rail displacement, there is a large amount of documents to this kind of rack and pinion servo straight line module in prior art to disclose, so do not do too much repeated description to its structure and principle, the following explains first linear module 3 and biax straight line module respectively:

the first linear module 3 is used for driving the whole biaxial linear module to move along the X-axis direction; specifically, the method comprises the following steps:

the first linear module 3 comprises a first slide rail 31 arranged along the X-axis direction and mounted on the frame 2, and two first sliding tables 32 slidably connected to the first slide rail 31, wherein the two first sliding tables 32 are driven by two first servo motors to move along the first slide rail 31; two biax straight line modules are located respectively on two first slip tables 32, so every biax straight line module is whole alright along X axle direction removal along with first slip table 32.

In the biaxial linear module:

as shown in fig. 1 and fig. 2, the second linear module 4 includes a second slide rail 41 arranged along the Y-axis direction, a second slide table 42 slidably connected to the second slide rail 41, and a second servo motor driving the second slide table 42 to slide, and the second servo motor drives the second slide table 42 to move in the Y-axis direction; the second slide rail 41 is fixedly mounted on the first slide table 32, and the first slide table 32 drives the second slide rail 41 to move along the X-axis direction.

The third linear module 5 comprises a third slide rail 51 arranged along the Z-axis direction, a third sliding table 52 connected to the third slide rail 51 in a sliding manner, and a third servo motor for driving the third sliding table 52 to slide, wherein the third servo motor drives the third sliding table 52 to move along the Z-axis direction; the third slide rail 51 is fixedly mounted on the second sliding table 42, and the second sliding table 42 drives the third slide rail 51 to move along the Y-axis direction; the mount 6 is fixedly mounted on the third slide table 52, and the third slide table 52 drives the mount 6 to move along the Z-axis direction.

In this embodiment, the first drilling device 11 and the rivet gun 12 are disposed on the mounting base 6; it should be noted that the two mounting seats 6 are each provided with a first drilling device 11 and a rivet gun 12, so as to machine two sides of the workpiece respectively.

Specifically, the first drilling device 11 may be an electric drill, and the riveting gun 12 is an existing automatic riveting gun 12; the first drilling devices 11 and the rivet guns 12 of the two mounting bases 6 are respectively used for processing two opposite side faces of a workpiece, the working ends (namely drill bits) of the first drilling devices 11 face the workpiece and are used for drilling rivet holes in the workpiece, and the working ends (namely gun heads) of the rivet guns 12 face the workpiece and are used for penetrating rivets in the rivet holes and pulling the rivets.

In this embodiment, the work end of first drilling equipment 11 and riveter 12 is located same water flat line, and so first drilling equipment 11 need not to control riveter 12 again and moves the height that adjusts riveter 12 in the Z axle direction after drilling, only need move riveter 12 in the Y axle direction, alright carry out subsequent rivet pulling operation.

The specific mounting structure for the first drilling device 11 and the rivet gun 12 is:

first drilling equipment 11 and riveter 12 all slide along the X axle direction and set up on mount pad 6, are equipped with the gliding first cylinder (viewing angle reason is not shown in the figure) of drive first drilling equipment 11 along the X axle direction at mount pad 6 on mount pad 6, drive first drilling equipment 11 through first cylinder and advance and retreat along the X axle direction.

A second cylinder (not shown in the view angle reason figure) for driving the rivet gun 12 to slide on the mounting base 6 along the X-axis direction is arranged on the mounting base 6, and the second cylinder drives the rivet gun 12 to move forward and backward along the X-axis direction.

The equipment also comprises a material pressing mechanism which moves along with the double-shaft linear module and is used for pressing the workpiece, and two side pressing mechanisms which are arranged on two sides of the conveying line 21 and are used for abutting against the side wall of the workpiece.

The two pressing mechanisms correspond to each two-axis linear module and are mainly used for pressing the upper end of the workpiece, so that the workpiece is firmly pressed on the conveying line 21; specifically, the pressing device comprises a first pressing bar 72 for pressing the upper end of the workpiece, and a first driving member 71 for driving the first pressing bar 72 to move along the Z-axis direction, wherein the first driving member 71 may be an air cylinder or a hydraulic cylinder, and the embodiment shows that the air cylinder is adopted: during installation, the air cylinder is vertically and fixedly installed on the first sliding table 32, or the air cylinder is vertically and fixedly installed on the second sliding rail 41, in the embodiment shown in fig. 2, the air cylinder is fixedly installed at the side of the second sliding rail 41, and during installation, the air cylinder is ensured not to be installed on a sliding path of the second sliding table 42 on the second sliding rail 41, so as to avoid interference with sliding of the second sliding table 42; the first pressing bar 72 is fixedly arranged at the shaft end of the piston rod of the air cylinder. Therefore, when the first sliding table 32 drives the second sliding rail 41 to integrally move along the X-axis direction, the cylinder can also move along the X-axis direction along with the second sliding rail, so as to adjust the distance between the two bead mechanisms according to the width of the workpiece, so that the two bead mechanisms are adapted to the workpiece, the upper end of the workpiece is ensured to be arranged with the beads, and when the workpiece is pressed, the first driving part 71 drives the beads to be pressed down to the upper end of the workpiece, so that the workpiece is pressed on the conveying line 21.

The lateral pressing mechanism is mainly used for pressing the side wall of the workpiece, the lateral pressing mechanism includes a second pressing bar 82 for pressing the side wall of the workpiece, and a second driving element 81 for driving the second pressing bar 82 to move along the X-axis direction, the second driving element 81 can be an air cylinder or a hydraulic cylinder, and the embodiment shows that the air cylinder is adopted: the cylinder is horizontally and fixedly installed on the rack 2, the second pressing strip 82 is fixed at the end of a piston rod shaft of the cylinder, the second pressing strip 82 is driven to move along the X-axis direction through the action of the cylinder until the second pressing strip abuts against the side wall of the bottom of the workpiece, and when the cylinder is used in particular, the pressing mechanisms on the two sides act to respectively drive the two pressing strips to abut against the two sides of the workpiece, so that the probability of deviation of the workpiece in the X-axis direction during drilling and riveting work is reduced. Meanwhile, the workpiece is firmly clamped on the conveying line 21 by being matched with the pressing of the material pressing mechanism, and the stability of subsequent drilling and riveting work is ensured.

The mounting seat 6 is also provided with a first scanning device 15 for horizontally scanning the workpiece along the Y-axis direction and a second scanning device 16 for vertically scanning the workpiece along the Z-axis direction; the first scanning device 15 and the second scanning device 16 can both adopt the existing laser scanning device, and the laser scanning is performed by the laser head in the device, and a large number of documents are disclosed in the prior art for the laser scanning device, so that the detailed description is omitted here.

The scanning of the workpieces by the laser head of the first scanning device 15 is performed to determine the number of workpieces and the length of each workpiece, where the length refers to the length of the workpiece in the Y-axis direction, while the first scanning device 15 moves with the mount 6 in the Y-axis direction.

When the second scanning device 16 moves along the mounting seat 6 along the Z-axis direction, the laser head of the second scanning device 16 completes scanning on the workpiece so as to determine the height of the workpiece.

In order to prevent the first slide rail 31 in the first linear module 3 from interfering the movement of the third slide rail 51 in the Y axis direction, as shown in fig. 2, the first linear module 3 includes two sets, and two the first linear module 3 is arranged side by side at intervals, and here the side by side refers to side by side in the Y axis direction, specifically, includes two first slide rails 31 side by side, and each first slide rail 31 is provided with two first sliding tables 32, and two first sliding tables 32 on the same first slide rail 31 are used for driving two biaxial linear modules to move respectively, the second slide rail 41 is arranged on two first slide rails 31 in a straddling manner, that is, the second slide rail 41 is fixed with two first sliding tables 32 (here, two first sliding tables 32 refer to first sliding tables 32 on different first slide rails 31) on the same side respectively. Through the arrangement, the two first slide rails 31 are arranged, so that a certain space is formed between the two first slide rails 31 in the Y-axis direction, and the third slide rail 51 moves in the Y-axis direction to move and give way, thereby avoiding the aforementioned interference problem.

In this embodiment, transfer chain 21 is the roller line, comprises a plurality of power drive pivoted conveying roller promptly, and the conveying roller axial sets up along the X axle direction, and the during operation drives the work piece on the conveying roller along Y axle direction conveying work piece through the rotation of conveying roller.

Because the workpiece has 4 side walls which are opposite to each other in pairs, the scheme can process two opposite side walls of the workpiece at one time, and the other two opposite side walls of the workpiece need to be processed at the moment, so that the other two opposite side walls can be processed after the first two side walls are processed. This embodiment is to carrying line further improvement, and is specific:

as shown in fig. 4, the conveying line 21 includes a first roller line 211 and a second roller line 212, the first roller line 211 and the second roller line 212 are both composed of a plurality of conveying rollers arranged in parallel side by side, and conveying surfaces of the first roller line 211 and the second roller line 212 are flush, that is, an upper wall of the conveying roller of the first roller line 211 is flush with an upper wall of the conveying roller of the second roller line 212 and located at the same height; the first roller line 211 is used for conveying workpieces along the Y-axis direction, the first roller line 211 is provided with a circular opening 213 in the middle, and the opening 213 is mainly used as a mounting position of the second roller line 212; the second roller line 212 is of a circular structure as a whole and is equivalent to a turntable, and the turntable is composed of a plurality of parallel conveying rollers side by side, so that the turntable not only can rotate integrally, but also can convey workpieces forwards; the second roller 212 is located in the opening 213 and is rotatably disposed, the second roller 212 is further connected to a driving machine (not shown in the figure), the driving machine drives the second roller 212 to rotate around the axis of the circular opening 213, the driving machine may be a motor-driven mode, and for the mode that the driving machine drives the disc-shaped roller to rotate, a large number of documents are disclosed in the prior art, and therefore detailed descriptions are omitted here.

In the initial state, the conveying direction of the second roller line 212 is the same as that of the first roller line 211, namely, the workpieces are conveyed along the Y-axis direction, and the subsequent processing steps are carried out to process the left side and the right side of the workpieces; if a plurality of workpieces are processed simultaneously, the second roller line 212 can only convey the workpieces for processing in the above manner, that is, cannot perform subsequent integral rotation processing; if only 1 workpiece is machined at one time, the workpiece is conveyed to the second roll line 212 according to an initial state at the moment to machine the left side and the right side of the workpiece, after machining of the left side and the right side of the workpiece is completed, the pressing mechanism retracts and the side pressing mechanism retracts to release clamping of the workpiece, then the driving mechanism drives the second roll line 212 to integrally rotate 90 degrees in the circumferential direction in the opening 213, at the moment, the front side wall and the rear side wall of the workpiece rotate to the left side position and the right side position, at the moment, the re-pressing mechanism and the side pressing mechanism are controlled to re-clamp the workpiece to re-machine the workpiece, and therefore, all 4 side walls of the workpiece are machined.

After riveting, the flange and the air pipe need to be subjected to glue injection sealing treatment at the joint, so in this embodiment, a glue gun 14 for gluing the workpiece is arranged on the mounting base 6, the glue gun 14 can adopt the existing automatic glue gun 14, the specific glue gun 14 is slidably mounted on the mounting base 6, a third cylinder (not shown in the figure for view angle reasons) is arranged on the mounting base 6, the glue gun 14 is driven by the third cylinder to move forwards and backwards on the mounting base 64 along the X-axis direction, when gluing, the glue gun 14 is driven by the mounting base 6 to move to the joint of the flange and the air pipe, then the glue gun 14 is controlled by the third cylinder to move forwards, then the mounting base 6 is driven by the double-axis linear module to move along the Y-axis direction, and in the process, the glue gun 14 moves along the joint to glue.

For some larger air pipes, reinforcing rods need to be penetrated through the air pipes in the later period, so in the embodiment, a second drilling device 13 is arranged, the air pipes are drilled through the second drilling device 13 to form reinforcing holes for the reinforcing rods to penetrate through, and the second drilling device 13 can also adopt electric drills; the second drilling device 13 is slidably mounted on the mounting base 64, and a fourth cylinder (not shown in the figure for reasons of view) is provided on the mounting base 64, and the second drilling device 1313 is driven by the fourth cylinder to move forward and backward on the mounting base 64 along the X-axis direction.

The advantages of this embodiment are: in this scheme, through setting up biax straight line module to utilize mount pad 6 to install rivet rifle 12 and first drilling equipment 11, so drive first drilling equipment 11 and rivet rifle 12 by biax straight line module and realize Y axle, Z axle direction motion, so alright realize drilling the flange at work piece both ends, rivet the operation, so than traditional manual work, can reduce intensity of labour undoubtedly, also improved work efficiency greatly.

Secondly, in this scheme, be equipped with two biax straight line modules at transfer chain 21 to all install first drilling equipment 11 and riveter 12 through mount pad 6 on every biax straight line module, so can bore the both sides of work piece simultaneously and rivet the operation, further improve work efficiency.

And because two biax straight line modules are all driven by first linear module 3, so can adjust the interval between two biax straight line modules, make it with the width looks adaptation of work piece, so can adapt to the processing of the work piece of multiple width size.

Finally, the scheme is provided with a material pressing mechanism for pressing the upper end of the workpiece and two side pressing mechanisms which are respectively arranged on two sides of the conveying line 21 and used for pressing the side walls of the workpiece, wherein the side pressing mechanisms can press two sides of the workpiece to enable the workpiece to be clamped between the pressing mechanisms on the two sides, the stability of the workpiece is guaranteed, meanwhile, the material pressing mechanism can press the upper end of the workpiece, the clamping stability of the workpiece is further improved, the material pressing mechanism is arranged on the double-shaft linear module and can move along with the double-shaft linear module integrally, and therefore when the double-shaft linear module moves and adjusts, the material pressing mechanism also moves along with the double-shaft linear module, and the material pressing mechanism is guaranteed to be adaptive to the workpiece and located above the workpiece.

Taking a plurality of workpieces as an example, the using method of the equipment comprises the following steps:

s1, the workpiece is first placed on the feed line 21, and the workpiece is fed from the feed line 21 in the Y-axis direction.

And S2, when the workpiece is conveyed to the processing area, the two side pressing mechanisms act to move the two second pressing strips 82 towards the middle until the two second pressing strips 82 are pressed against the side walls on the two sides of the workpiece, so that the side pressing work is completed.

S3, driving the two double-axis linear modules to approach to the middle by the first linear module 3, and moving the pressing mechanism and the mounting seat 6 together to approach the workpiece until reaching the processing position.

And S4, the pressing mechanism acts to move the two first pressing strips 72 downwards until the two first pressing strips are pressed against the upper end of the workpiece, so that the pressing operation is completed. At this time, the workpiece is firmly pressed on the conveying line 21 by the first pressing strip 72 and the second pressing strip 82.

S5, start scanning: the third linear module 5 drives the mounting seat 6 to move upwards integrally along the Z-axis direction, in the process, a laser head of the second scanning device 16 starts scanning to determine the height H of a workpiece, wherein the height of the workpiece refers to the upper end position of the workpiece, and then the third linear module 5 drives the first drilling device 11 to move to the upper flange drilling and riveting height position according to the determined height H of the workpiece, wherein the drilling and riveting height position can be obtained by subtracting a preset reference value from the height of the workpiece; then the second linear module 4 drives the third linear module 5 and the mounting seat 6 to move integrally along the Y-axis direction, in the process, the laser head of the first scanning device 15 starts to scan the workpieces along the Y-axis direction, so as to determine the number of the workpieces and the length L of each workpiece.

S6, beginning to drill and rivet: according to the scanning result determined in the step S5, the second linear module 4 drives the third linear module 5 and the mounting seat 6 to move along the Y axis direction again, in this process, the first drilling device 11 on the mounting seat 6 drills holes in sequence on each workpiece to form a rivet hole, and after the drilling is finished, the second linear module 4 drives the mounting group to move along the Y axis direction, and the rivet is sequentially inserted into the rivet hole through the rivet gun 12 and is subjected to rivet pulling. Of course, a rivet hole may be drilled and then subjected to a riveting operation, which may be specifically selected according to actual needs.

In this step, as shown in fig. 3, the first rivet hole and the last rivet hole of each workpiece are located at a distance G (generally 20mm by default) from the edge line of the workpiece in the Y-axis direction.

The number of actual rivet holes, i.e., the number of holes ═ Round ((L-2G)/X) + 1;

the actual rivet hole spacing, i.e. the hole spacing of (L-2G)/Round ((L-2G)/X),

in the above, Round is a Round function, X is an input reference coefficient, and the reference coefficient can be modified according to the actual situation, so that when G is determined, for example, G is 120mm, the number of holes and the hole pitch can be controlled by only adjusting the value of X.

S7, after the flange drilling and riveting are finished, the glue gun 14 is driven to the joint of the flange and the air pipe (the area indicated by the part a in the figure 3) through the double-shaft linear module, and the glue gun 14 is driven to sequentially glue all the workpieces along the Y-axis direction.

The present embodiment is mainly used for operations such as drilling and riveting glue on a flange above a workpiece.

The above are only typical examples of the present invention, and besides, the present invention may have other embodiments, and all technical solutions formed by equivalent substitutions or equivalent transformations fall within the scope of the present invention.