CN113814737B - A flexible processing equipment of alloy ex-trusions for aluminum-wood door leaf is bordured - Google Patents

Abstract

The invention discloses alloy profile flexible processing equipment for aluminum-wood door leaf edge covering, which relates to the technical field of door and window processing, and comprises a fixed workbench, a B processing group, a movable workbench and an A processing assembly which are arranged on a frame, wherein the fixed workbench and the movable workbench are respectively positioned at two ends of the frame, the movable workbench is arranged on the frame through a length adjusting mechanism, the B processing group and the A processing assembly are respectively positioned at two ends of the frame, the B processing group and the A processing assembly respectively comprise one or more processing units such as a fixed-length saw, a drill bit and a milling V-groove saw, and the fixed-length saw, the drill bit and the milling V-groove saw are arranged on the B processing group or the A processing assembly side by side; through the scheme, the [ -shaped aluminum alloy frame is processed and finished on the same equipment, the overall processing efficiency is high, and the rapid production of enterprises is facilitated.

Description

A flexible processing equipment of alloy ex-trusions for aluminum-wood door leaf is bordured

Technical Field

The invention relates to the technical field of door and window processing, in particular to flexible processing equipment for an alloy section used for aluminum-wood door leaf edge wrapping.

Background

With the rapid development of social modernization, the material construction civilization is developed more and more quickly. The door and window not only greatly improves the practicability and the aesthetic property, but also greatly changes the material style. The aluminum alloy door and window becomes a trend of door and window development in the modern society due to the characteristics of material saving, elegant appearance and the like.

The aluminum alloy door is formed by filling a door plate in an aluminum alloy rectangular frame. In order to keep the attractiveness of the rectangular frame, four surfaces of the rectangular frame perpendicular to the door panel need to be wrapped by alloy profiles, wherein two surfaces perpendicular to the ground need to be wrapped by the alloy profiles, and four corners of the rectangular frame need to be wrapped. The common method is that after the length of the alloy section bar is manually measured and marked, the alloy section bar is manually bent for edge covering, the production efficiency is low, and for the alloy section bar with reinforcing ribs, the bending is difficult and the flatness is poor after the edge covering.

Therefore, the flexible processing equipment for the alloy section bar of the aluminum-wood door leaf edge is provided to solve the problems.

Disclosure of Invention

The invention aims to provide flexible processing equipment for an alloy section used for aluminum-wood door leaf edge wrapping, which aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a flexible processing equipment of alloy ex-trusions for bordure of aluminum-wood door leaf, is including setting up fixed work platform, B processing group, activity workstation and the A processing subassembly in the frame, fixed work platform with the activity workstation is located respectively the both ends of frame, the activity workstation passes through length adjustment mechanism and sets up in the frame, B processing group with the A processing subassembly is located respectively the both ends of frame, B processing group with the A processing subassembly all includes one or more processing unit such as scale saw, drill bit and milling V groove saw, the scale saw the drill bit with it is in to mill V groove saw side by side the B processing group or on the A processing subassembly, fixed work platform with set up bending mechanism and positioning mechanism on the activity workstation.

Furthermore, each bending mechanism is arranged on the movable workbench or the fixed workbench through a connecting plate, and each bending mechanism comprises two bending mechanisms respectively arranged on two sides of the connecting plate:

the pre-folding roller comprises a third cylinder, a convex plate and a pushing roller, wherein the third cylinder is arranged on the connecting plate, the output end of the third cylinder is fixedly connected with the convex plate, and the vertical side wall of the convex plate is connected with the pushing roller through a transverse rotating shaft; and

the right-angle bending part comprises a bending pushing block and a fourth air cylinder, the fourth air cylinder is arranged on the connecting plate, and the output end of the fourth air cylinder is connected with the bending pushing block;

and the two right-angle bending parts of the two bending mechanisms are positioned between the two pre-folding rollers.

Further, the length adjustment mechanism includes:

the driving assembly comprises a synchronous belt, a first servo motor, a first gear, a second gear, a first connecting seat and a first threaded rod, the first servo motor and the first threaded rod are arranged on the rack, the output end of the first servo motor is fixedly connected with the first gear, the first gear is meshed with the synchronous belt, the synchronous belt is meshed with the second gear, the second gear is fixedly connected with the first threaded rod, the first connecting seat is in threaded connection with the first threaded rod through a threaded sleeve, and the first connecting seat is fixedly installed at the bottom of the movable workbench to drive the movable workbench to move; and

the guide assembly comprises a first limiting slide block and a first limiting slide rail, the first limiting slide rail is symmetrically installed at the top of the rack, the first limiting slide block is connected with the first limiting slide rail in a limiting sliding mode, and the first limiting slide block is symmetrically installed at the bottom of the movable workbench.

Furthermore, the B processing group and the A processing assembly are arranged on the rack through an X-axis driving structure and a Y-axis driving structure, the X-axis driving structure is connected with the rack in a sliding mode, and the Y-axis driving structure is connected with the X-axis driving structure in a sliding mode.

Furthermore, the X-axis driving structure comprises a side toothed plate, a second limit slide rail, a U-shaped support frame, a second limit slide block, a second servo motor, a side mounting frame and a driving gear ring, the second limit slide rail is arranged on the rack, the side toothed plate is arranged on the inner wall of the second limit slide rail, the bottom of the U-shaped support frame is connected with the second limit slide rail through the second limit slide block, the second servo motor is arranged on the U-shaped support frame through the side mounting frame, and the output end of the second servo motor is connected with the driving gear ring matched with the side toothed plate for use;

y axle drive structure includes installation frame, third servo motor, the spacing slide rail of third, third threaded rod, the spacing slider of third and third connecting seat, the spacing slide rail symmetry of third is installed the top of U-shaped support frame, third servo motor sets up the lateral wall department of U-shaped support frame, third servo motor output with the third threaded rod is connected, the bottom of installation frame is passed through the spacing slider of third with the spacing slide linkage of third, the bottom of installation frame is passed through the third connecting seat with the third threaded rod is connected.

Furthermore, the fixed length saw, the drill bit and the V-groove milling saw are arranged on the mounting rack through respective lifting cylinders.

Furthermore, the fixed workbench and the movable workbench comprise a supporting structure, and the alloy section is arranged in the supporting structure.

Furthermore, the positioning mechanism comprises a spinning positioning mechanism and a side pressure positioning mechanism which are arranged on the fixed workbench and the movable workbench, and the side pressure positioning mechanism and the spinning positioning mechanism are arranged on one side of the supporting structure.

Furthermore, the movable workbench is far away from one end of the fixed workbench is provided with a positioning backer, the positioning backer comprises a sixth cylinder, a limit baffle and a transverse backing plate, the transverse backing plate is arranged on the movable workbench, the sixth cylinder is arranged on the transverse backing plate, and the output end of the sixth cylinder is connected with the limit baffle.

The beneficial effects of the invention are:

according to the invention, a length adjusting structure is required to drive a fixed workbench to move to a set position according to processing requirements, then a positioning structure is adjusted, then the fixed workbench is placed in a mounting groove, a front side pressure positioning mechanism, a rear side pressure positioning mechanism and a spinning positioning mechanism are used for positioning alloy section bars, then an X-axis moving structure and a Y-axis moving structure are matched to respectively drive a B-axis processing assembly and an A-axis processing assembly, then a V-groove milling saw, a drill bit and a third processing structure are driven to perform corresponding processing, then a bending mechanism is used for bending, finally the front side pressure positioning mechanism, the rear side pressure positioning mechanism and the spinning positioning mechanism are used for compressing a bent workpiece in an open manner, and a [ -shaped aluminum alloy frame is processed and finished on the same equipment.

Drawings

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

FIG. 1 is a flow chart of processing of a [ "shaped aluminum alloy frame of the present invention;

FIG. 2 is a schematic structural view of the present invention;

FIG. 3 is a top right view of the structure of the present invention;

FIG. 4 is a structural elevation view of the present invention;

FIG. 5 is a top view of the structure of the present invention;

FIG. 6 is a schematic view of the mounting frame and its connection structure of the present invention;

FIG. 7 is a schematic view of a spinning positioning mechanism of the present invention;

FIG. 8 is a schematic structural view of a bending mechanism of the present invention;

FIG. 9 is a schematic view of the movable table and its connection structure of the present invention;

FIG. 10 is a schematic view of a front pressure positioning mechanism of the present invention;

FIG. 11 is a schematic view of a rear side pressure positioning mechanism of the present invention;

FIG. 12 is an enlarged view of the structure at A of FIG. 2 according to the present invention;

in the drawings, the components represented by the respective reference numerals are listed below:

1. the device comprises a rear rack 2, a front rack 3, a mounting groove 4, a fixed workbench 5, a front side pressure positioning mechanism 51, a first air cylinder 52, a first limit straight plate 6, a movable workbench 7, a side toothed plate 8.B machining assembly 9, a first supporting plate 10, a rear side pressure positioning mechanism 101, a second air cylinder 102, a limiting column 11, a spinning positioning mechanism 111, a side mounting plate 112, a rotating compaction air cylinder 113, a compaction block 12.A machining assembly 13, a mounting rack 14, a first limit sliding block 15, a first limit sliding rail 16, a synchronous belt 17, a second limit sliding rail 18, a box 19, a V groove milling saw 20, a drill bit 21, a fixed size saw 22, a lifting air cylinder 23, a first servo groove saw 20, a first limiting sliding block, a first limiting sliding rail 16, a synchronous belt 17, a second limiting sliding rail 18, a box the motor 24, the first gear 25, the second gear 26, the second servo motor 27, the third limit slide rail 28, the U-shaped support frame 29, the third threaded rod 30, the second limit slide block 31, the third limit slide block 32, the first straight groove 33, the third servo motor 34, the side mounting frame 35, the bending mechanism 351, the third air cylinder 352, the convex plate 353, the pushing roller 354, the connecting plate 355, the bending pushing block 356, the fourth air cylinder 36, the driving gear ring 37, the waste material groove 38, the sixth air cylinder 39, the second support plate 40, the first connecting seat 41, the third connecting seat 42, the limit baffle 43, the transverse backing plate 44, the second straight groove 45 and the first threaded rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The present invention will be further described with reference to the following examples.

Examples

As shown in fig. 2-6, a flexible processing device for an alloy section used for aluminum-wood door leaf edge covering, the frame comprises a rear frame 1 and a front frame 2, and comprises a fixed workbench 4, a B processing group 8, a movable workbench 6 and an a processing assembly 12 which are arranged on the frame, wherein the fixed workbench 4 and the movable workbench 6 are respectively positioned at two ends of the front frame 2;

as shown in fig. 1 and 2, the fixed table 4 and the movable table 6 comprise a support structure, and the alloy section is arranged in the support structure.

The supporting mechanism comprises a mounting groove 3, a first supporting plate 9 and a second supporting plate 39, the mounting groove 3 used for mounting the alloy section is formed in the front end and the rear end of the top of the first supporting plate 9 and the top of the second supporting plate 39, the first supporting plate 9 is fixedly mounted on the fixed workbench 4, and the second supporting plate 39 is fixedly mounted on the movable workbench 6.

The fixed table 4 and the movable table 6 are provided with a bending mechanism 35 and a positioning mechanism.

As shown in fig. 2, 3, 8 and 12, each bending mechanism 35 is disposed on the movable table 6 or the fixed table 4 through a connecting plate 354, and each bending mechanism 35 includes:

the pre-bending roller comprises a third cylinder 351, a convex plate 352 and a pushing roller 353, wherein the third cylinder 351 is arranged on a connecting plate 354, the convex plate 352 is fixedly connected to the output end of the third cylinder 351, the vertical side wall of the convex plate 352 is connected with the pushing roller 353 through a transverse rotating shaft, and the third cylinder 351 pushes the pushing roller 353 to move through the convex plate 352 so as to pre-bend a workpiece subjected to V-groove milling; and

the right-angle bending part comprises a bending pushing block 355 and a fourth air cylinder 356, the fourth air cylinder 356 is arranged on the connecting plate 354, the output end of the fourth air cylinder 356 is connected with the bending pushing block 355, and the fourth air cylinder 356 pushes the bending pushing block 355 to move so as to bend the pre-bent workpiece for the second time, so that the bending of the workpiece after the V-shaped groove is milled is realized;

the two right-angle bending parts of the two bending mechanisms 35 are positioned between the two pre-folding rollers.

The top parts of the outer ends of the fixed workbench 4 and the movable workbench 6 are provided with a first straight groove 32 and a second straight groove 44, the bending pushing block 355 moves in the first straight groove 32, and the pushing roller 353 moves in the second straight groove 44, so that the influence of the bending pushing block 355 and the pushing roller 353 on the alloy section is avoided when the alloy section is not used.

The positioning mechanism comprises a spinning positioning mechanism 11 and a side pressure positioning mechanism which are arranged on the fixed workbench 4 and the movable workbench 6, and the side pressure positioning mechanism and the spinning positioning mechanism 11 are arranged on one side of the supporting structure.

The lateral pressure positioning mechanism comprises a front lateral pressure positioning mechanism 5 and a rear lateral pressure positioning mechanism 10;

as shown in fig. 2 and 7, the rear side pressure positioning mechanism 10 includes a second cylinder 101 and a limit column 102, the second cylinder 101 is installed on the side walls of the fixed workbench 4 and the movable workbench 6, the output end of the second cylinder 101 is fixedly connected with the limit column 102, and the second cylinder 101 pushes the limit column 102 to move to contact with the side wall of the rear side alloy profile to realize horizontal limit on the rear side alloy profile.

As shown in fig. 2-6, the front side pressure positioning mechanism 5 includes a first cylinder 51 and a first limit straight plate 52, the first cylinder 51 is installed on the fixed workbench 4 and the movable workbench 6, the output end of the first cylinder 51 is fixedly connected with the first limit straight plate 52, and the first cylinder 51 pushes the first limit straight plate 52 to move to contact with the side wall of the alloy profile on the front side to realize horizontal limit on the alloy profile on the front side.

As shown in fig. 2-6, the spinning positioning mechanism 11 includes a side mounting plate 111, a rotary pressing cylinder 112 and a pressing block 113, the side mounting plate 111 is fixedly connected with the rotary pressing cylinder 112, the output end of the rotary pressing cylinder 112 is fixed with the pressing block 113, the side mounting plate 111 is mounted on the inner and outer walls of the fixed workbench 4 and the inner and outer walls of the movable workbench 6, and the rotary pressing cylinder 112 pushes the pressing block 113 to move to contact with the top of the alloy profile to vertically limit the alloy profile;

the movable working table 6 is arranged on the front frame 2 through a length adjusting mechanism;

the length adjustment mechanism includes:

the driving assembly comprises a synchronous belt 16, a first servo motor 23, a first gear 24, a second gear 25, a first connecting seat 40 and a first threaded rod 45, the first servo motor 23 and the first threaded rod 45 are arranged on the front rack 2, the output end of the first servo motor 23 is fixedly connected with the first gear 24, the synchronous belt 16 is connected with the first gear 24 in a meshed mode, the synchronous belt 16 is connected with the second gear 25 in a meshed mode, the second gear 25 is fixedly connected with the first threaded rod 45, the first connecting seat 40 is in threaded connection with the first threaded rod 45 through a threaded sleeve, and the first connecting seat 40 is fixedly installed at the bottom of the movable workbench 6 to drive the movable workbench 6 to move; and

the guide assembly comprises a first limiting slide block 14 and a first limiting slide rail 15, the first limiting slide rail 15 is symmetrically installed at the top of the front frame 2, the first limiting slide block 14 is in limiting sliding connection with the first limiting slide rail 15, and the first limiting slide block 14 is symmetrically installed at the bottom of the movable workbench 6.

As shown in fig. 1-6, the processing group B8 and the processing group a 12 are respectively located at two ends of the rear frame 1;

as shown in fig. 2-6, the B processing group 8 and the a processing assembly 12 are disposed on the rear frame 1 through an X-axis driving structure and a Y-axis driving structure, the X-axis driving structure is slidably connected to the rear frame 1, and the Y-axis driving structure is slidably connected to the X-axis driving structure.

The X-axis driving structure comprises a side toothed plate 7, a second limiting slide rail 17, a U-shaped support frame 28, a second limiting slide block 30, a second servo motor 33, a side mounting frame 34 and a driving gear ring 36, the second limiting slide rail 17 is arranged on the rear rack 1, the side toothed plate 7 is arranged on the inner wall of the second limiting slide rail 17, the bottom of the U-shaped support frame 28 is connected with the second limiting slide rail 17 through the second limiting slide block 30, the second servo motor 33 is arranged on the U-shaped support frame 28 through the side mounting frame 34, and the output end of the second servo motor 33 is connected with the driving gear ring 36 matched with the side toothed plate 7;

a case 18 is installed on the side wall of the installation frame 13, and a third servo motor 33 is arranged in the case 18

The Y-axis driving structure comprises an installation rack 13, a third servo motor 26, a third limiting slide rail 27, a third threaded rod 29, a third limiting slide block 31 and a third connecting seat 41, the third limiting slide rail 27 is symmetrically installed at the top of the U-shaped supporting frame 28, the third servo motor 26 is arranged at the side wall of the U-shaped supporting frame 28, the output end of the third servo motor 26 is connected with the third threaded rod 29, the bottom of the installation rack 13 is connected with the third limiting slide rail 27 through the third limiting slide block 31, and the bottom of the installation rack 13 is connected with the third threaded rod 29 through the third connecting seat 41.

As shown in fig. 2-6, the B processing assembly 8 and the a processing assembly 12 have the same structure, each of the B processing assembly 8 and the a processing assembly 12 includes one or more processing units such as a fixed-length saw 21, a drill 20, and a V-groove milling saw 19, and the fixed-length saw 21, the drill 20, and the V-groove milling saw 19 are arranged side by side on the B processing assembly 8 or the a processing assembly 12;

the front side wall of installing frame 13 has lift cylinder 22, and the front side of installing frame 13 is passed through guide structure and is handled milling V groove saw 19, drill bit 20 and scale saw 21 direction, mills V groove saw 19 and is used for milling the V groove, and drill bit 20 is used for drilling, mills the breach, mills the locked groove, and scale saw 21 is used for sawing, and the scale saw 21 that A processing component 12 is connected is used for sawing the waste material, and the scale saw 21 that B processing component 8 is connected cuts the original paper of formation to sawing of alloy ex-trusions.

As shown in fig. 9 and 12, one end of the movable workbench 6 far from the fixed workbench 4 is provided with a positioning backer, the positioning backer comprises a sixth air cylinder 38, a limit baffle 42 and a transverse backing plate 43, the transverse backing plate 43 is arranged on the movable workbench 6, the sixth air cylinder 38 is arranged on the transverse backing plate 43, and the output end of the sixth air cylinder 38 is connected with the limit baffle 42.

Sixth cylinder 38 promotes limit baffle 42 and moves to limit position before the alloy ex-trusions installation, and then alloy ex-trusions and limit baffle 42 laminating contact when the alloy ex-trusions installation conveniently carry out spacing processing to the tip of alloy ex-trusions, do benefit to and carry out fixed length and handle.

As shown in fig. 3 and 9, the fixed worktable 4 is further connected with a waste chute 37 for collecting waste materials below the positioning structure, and the waste materials sawed by the fixed length saw 21 fall into the waste chute 37, so that the waste materials are conveniently collected.

When the length-adjustable device is used, the first servo motor 23 of the length-adjustable structure is driven to rotate according to the processing requirement, the first gear 24 drives the second gear 25 to rotate through the synchronous belt 16, the second gear 25 drives the first threaded rod 45 to rotate, the first threaded rod 45 drives the fixed workbench 4 to move through the first connecting seat 40, the fixed workbench 4 is driven to move to a set position under the action of the first limit slide block 14 and the first limit slide rail 15, then the sixth cylinder 38 of the positioning structure pushes the preset position of the limit baffle plate 42, the fixed workbench is placed in the installation groove 3, the right end of the installation groove 3 is in contact with the left end of the limit baffle plate 42, the first cylinder 51 of the front side pressure positioning mechanism 5 drives the first limit straight plate 52 to limit the alloy section on the front side, the second cylinder 101 of the rear side pressure positioning mechanism 10 drives the limit column 102 to limit the alloy section on the rear side, A rotary pressing cylinder 112 of a spinning positioning mechanism 11 drives a pressing block 113 to move downwards to press an alloy profile to position the alloy profile, then an X-axis moving structure and a Y-axis moving structure are matched to respectively drive a B processing assembly 8 and an A processing assembly 12, then a lifting cylinder 22 respectively drives a milling V groove saw 19, a drill bit 20 and a fixed length saw 21 to perform corresponding processing, the fixed length saw 21 connected with the A processing assembly 12 is used for saw cutting waste materials, the fixed length saw 21 connected with the B processing assembly 8 cuts off an original part of the alloy profile to form a saw cut, the milling V groove saw 19 is used for milling a V groove, the drill bit 20 is used for drilling, milling a notch and milling a locking groove, the fixed length saw 21 is used for saw cutting, after the processing is finished, a sixth cylinder 38 drives a limit baffle 42 to move to be separated from the end part of the original part, and then a fourth cylinder 356 of a bending mechanism 35 pushes a bending pushing block 355 to move to pre-bend the workpiece after the milling V groove, then the third cylinder 351 pushes the pushing roller 353 to move through the convex plate 352 to bend the pre-bent workpiece for the second time, the workpiece is bent after the V-shaped groove is milled, finally the front side pressure positioning mechanism 5, the rear side pressure positioning mechanism 10 and the spinning positioning mechanism 11 open and press the bent workpiece, the [ -shaped aluminum alloy frame is machined and finished on the same equipment, the overall machining efficiency is high, and the enterprise rapid production is facilitated, meanwhile, the two sets of installation grooves 3 can simultaneously machine and process two sets of alloy sections, and the machining efficiency is further improved.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (8)

1. The alloy section bar flexible processing equipment for aluminum-wood door leaf edge covering is characterized by comprising a fixed workbench (4), a B processing group (8), a movable workbench (6) and an A processing assembly (12) which are arranged on a rack, wherein the fixed workbench (4) and the movable workbench (6) are respectively positioned at two ends of the rack, the movable workbench (6) is arranged on the rack through a length adjusting mechanism, the B processing group (8) and the A processing assembly (12) are respectively positioned at two ends of the rack, the B processing group (8) and the A processing assembly (12) respectively comprise a fixed length saw (21), a drill bit (20) and a milling V groove saw (19), the fixed length saw (21), the drill bit (20) and the milling V groove saw (19) are arranged on the B processing group (8) or the A processing assembly (12) side by side, and a bending mechanism (35) and a positioning mechanism are arranged on the fixed workbench (4) and the movable workbench (6);

each bending mechanism (35) is arranged on the movable workbench (6) or the fixed workbench (4) through a connecting plate (354), and each bending mechanism (35) comprises a connecting plate (354) on two sides:

the pre-folding roller comprises a third cylinder (351), a convex plate (352) and a pushing roller (353), wherein the third cylinder (351) is arranged on the connecting plate (354), the output end of the third cylinder (351) is fixedly connected with the convex plate (352), and the vertical side wall of the convex plate (352) is connected with the pushing roller (353) through a transverse rotating shaft; and

the right-angle bending part comprises a bending pushing block (355) and a fourth air cylinder (356), the fourth air cylinder (356) is arranged on the connecting plate (354), and the output end of the fourth air cylinder (356) is connected with the bending pushing block (355);

and the two right-angle bending parts of the two bending mechanisms (35) are positioned between the two pre-bending rollers.

2. The flexible processing equipment for the alloy profiles for the serging of the aluminum-wood door leaves as claimed in claim 1, wherein the length adjusting mechanism comprises:

the driving assembly comprises a synchronous belt (16), a first servo motor (23), a first gear (24), a second gear (25), a first connecting seat (40) and a first threaded rod (45), the first servo motor (23) and the first threaded rod (45) are arranged on the rack, the first gear (24) is fixedly connected with the output end of the first servo motor (23), the synchronous belt (16) is connected with the first gear (24) in a meshed mode, the second gear (25) is connected with the synchronous belt (16) in a meshed mode, the first threaded rod (45) is fixedly connected with the second gear (25) in a meshed mode, the first connecting seat (40) is in threaded connection with the first threaded rod (45) through a threaded sleeve, the first connecting seat (40) is fixedly installed at the bottom of the movable workbench (6), and the movable workbench (6) is driven to move; and

the guide assembly comprises a first limiting slide block (14) and a first limiting slide rail (15), wherein the first limiting slide rail (15) is symmetrically installed at the top of the rack, the first limiting slide block (14) is connected with the first limiting slide rail (15) in a limiting sliding mode, and the first limiting slide block (14) is symmetrically installed at the bottom of the movable workbench (6).

3. The flexible processing equipment for the alloy profiles used for hemming aluminum-wood door leaves according to claim 1, wherein the processing group B (8) and the processing group A (12) are arranged on the rack through an X-axis driving structure and a Y-axis driving structure, the X-axis driving structure is connected with the rack in a sliding manner, and the Y-axis driving structure is connected with the X-axis driving structure in a sliding manner.

4. The flexible processing device for the alloy section bar of the aluminum-wood door leaf edge covering of the claim 3, is characterized in that,

the X-axis driving structure comprises a side toothed plate (7), a second limiting sliding rail (17), a U-shaped supporting frame (28), a second limiting sliding block (30), a second servo motor (33), a side mounting frame (34) and a driving gear ring (36), the second limiting sliding rail (17) is arranged on the rack, the side toothed plate (7) is arranged on the inner wall of the second limiting sliding rail (17), the bottom of the U-shaped supporting frame (28) is connected with the second limiting sliding rail (17) through the second limiting sliding block (30), the second servo motor (33) is arranged on the U-shaped supporting frame (28) through the side mounting frame (34), and the output end of the second servo motor (33) is connected with the driving gear ring (36) matched with the side toothed plate (7) for use;

y axle drive structure includes installation frame (13), third servo motor (26), third spacing slide rail (27), third threaded rod (29), third limit slide block (31) and third connecting seat (41), third limit slide rail (27) symmetry is installed the top of U-shaped support frame (28), third servo motor (26) set up the lateral wall department of U-shaped support frame (28), third servo motor (26) output with third threaded rod (29) are connected, the bottom of installation frame (13) is passed through third limit slide block (31) with third spacing slide rail (27) are connected, the bottom of installation frame (13) is passed through third connecting seat (41) with third threaded rod (29) are connected.

5. The flexible machining device for the alloy profiles used for hemming aluminum-wood door leaves according to claim 4, characterized in that the sizing saw (21), the drill bit (20) and the milling V-groove saw (19) are respectively arranged on the installation rack (13) through respective lifting cylinders (22).

6. The flexible processing equipment for the alloy profiles used for serging the aluminum-wood door leaves as claimed in claim 1, characterized in that the fixed workbench (4) and the movable workbench (6) comprise a supporting structure, and the alloy profiles are arranged in the supporting structure.

7. The aluminum-wood door leaf hemming alloy section bar flexible processing device according to claim 6, wherein the positioning mechanism comprises a spinning positioning mechanism (11) and a side pressure positioning mechanism which are arranged on the fixed workbench (4) and the movable workbench (6), and the side pressure positioning mechanism and the spinning positioning mechanism (11) are arranged on one side of the supporting structure.

8. The flexible processing equipment for the alloy profiles used for aluminum-wood door leaf binding according to claim 1, characterized in that one end of the movable workbench (6) far away from the fixed workbench (4) is provided with a positioning backer, the positioning backer comprises a sixth cylinder (38), a limit baffle (42) and a transverse backing plate (43), the transverse backing plate (43) is arranged on the movable workbench (6), the sixth cylinder (38) is arranged on the transverse backing plate (43), and the output end of the sixth cylinder (38) is connected with the limit baffle (42).

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