CN108672971B

CN108672971B - Working method of cold welding device for aluminum alloy window

Info

Publication number: CN108672971B
Application number: CN201810586605.1A
Authority: CN
Inventors: 段满红; 朱蕾; 段小宁
Original assignee: Zhejiang Amsi Wallpaper Co ltd
Current assignee: Shaoxing Yonglong Knitting Embroidery Co ltd
Priority date: 2018-06-06
Filing date: 2018-06-06
Publication date: 2020-10-27
Anticipated expiration: 2038-06-06
Also published as: CN108672971A

Abstract

The invention relates to the technical field of aluminum alloy processing, in particular to a working method of a cold welding device of an aluminum alloy window, which comprises a rotating mechanism, a positioning mechanism, an adjusting mechanism and a welding mechanism, the aluminum alloy window frame welding mechanism has the advantages that workers can complete welding processing of the aluminum alloy window frame, dislocation of aluminum alloy materials in the welding process is avoided, the occupied space is small, the cost is low, and the aluminum alloy window frame welding mechanism is suitable for being used in small shop processing rooms.

Description

Working method of cold welding device for aluminum alloy window

Technical Field

The invention relates to the technical field of aluminum alloy processing, in particular to a working method of a cold welding device of an aluminum alloy window.

Background

The aluminum alloy window is a window with a frame and sash structure made of aluminum alloy building profiles. The aluminum alloy window has the advantages of attractive appearance, sealing and high strength, and is widely applied to the field of constructional engineering.

Present large-scale aluminum alloy window processing factory can both realize its automated processing, but still make through manual welding in some miniature aluminum alloy window processing shops, the great automation equipment can't be placed owing to the place of production is less in the small-size processing shop of aluminum alloy window, and the small-size processing shop fund of aluminum alloy window is also limited, and current aluminum alloy window automatic processing equipment cost is higher, the manual work is when the welding, aluminum alloy material is difficult to align in the place of connecting, also misplace easily in welding process, consequently, need the cold welding device of an aluminum alloy window to cooperate the workman to accomplish the welding of aluminum alloy window, can help the fixed aluminum alloy window frame of workman and accelerate aluminum alloy window welded speed, and the device cost is lower, occupation space is less.

Disclosure of Invention

The invention aims to provide a working method of a cold welding device of an aluminum alloy window, which aims to solve the problems in the background technology.

The technical scheme of the invention is as follows: including rotary mechanism, positioning mechanism, adjustment mechanism and welding mechanism, the equal fixed mounting of positioning mechanism and adjustment mechanism is on rotary mechanism, welding mechanism is located rotary mechanism's side, adjustment mechanism includes two adjusting part, every adjusting part includes driver part and two adjusting part, two adjusting part all with driver part fixed connection, positioning mechanism includes four positioning component, and four positioning component install respectively on four adjusting part, welding mechanism includes welding component, removal subassembly and displacement subassembly, the displacement subassembly is located rotary mechanism's side, remove the upper end of unit mount at the displacement subassembly, welding component fixed mounting is on removing the subassembly.

In a preferred embodiment of the invention, the rotating mechanism comprises an installation platform, a rotating motor, a first rotating disk and a second rotating disk, the first rotating disk and the second rotating disk are both vertically arranged, a connecting block for connecting the first rotating disk and the second rotating disk is arranged between the first rotating disk and the second rotating disk, the rotating motor is horizontally arranged on the installation platform, and the output end of the rotating motor is fixedly connected with the first rotating disk.

In a preferred embodiment of the present invention, one side of the second rotating disk is provided with four sliding rails arranged in a groined shape, two ends of each sliding rail are provided with four sliding grooves, the second rotating disk is provided with four sliding groove groups distributed in a rectangular shape, and each sliding groove group comprises two sliding grooves which are parallel to each other.

In a preferred embodiment of the present invention, each of the adjusting components includes a material discharging block, a material discharging slot is disposed on one side of the material discharging block, four connecting pieces are disposed at two ends of the other side of the material discharging block, and a roller wheel which is in rolling fit with the sliding slot is disposed on one side of each connecting piece.

In a preferred embodiment of the present invention, each of the driving components includes a driving motor and a driving rod, the driving rod penetrates through a connecting block, the driving motor is installed between the first rotating disk and the second rotating disk, an output end of the driving motor is fixedly connected to the driving rod, two ends of the driving rod are respectively provided with a first thread and a second thread, pitches of the first thread and the second thread are the same, and spiral directions of the first thread and the second thread are opposite, two ends of the driving rod are respectively provided with a fixing block, the two fixing blocks are respectively in threaded fit with the first thread and the second thread, one side of the fixing block is provided with two connecting strips in sliding fit with the sliding groove, and one end of each connecting strip is fixedly connected to the material.

In a preferred embodiment of the invention, each positioning assembly comprises two positioning plates and two positioning cylinders, the cross sections of the two positioning plates are L-shaped, the two positioning plates are respectively installed at two ends of the discharging block, the two positioning cylinders are respectively and fixedly connected with the two positioning plates, output ends of the two positioning cylinders respectively penetrate through the discharging block and extend into the discharging groove, the output ends of the two positioning cylinders are respectively provided with a positioning plate, and one side of each positioning plate is provided with a gasket.

In a preferred embodiment of the present invention, the displacement assembly includes a lifting platform and a screw rod sliding table, the lifting platform is located beside the rotating mechanism, and the screw rod sliding table is horizontally disposed at an upper end of the lifting platform.

In a preferred embodiment of the present invention, the moving assembly comprises a moving plate, a moving cylinder and a supporting plate, the moving plate is fixedly arranged on the sliding block of the screw rod sliding table, the moving cylinder is horizontally arranged at the upper end of the moving plate, the bearing plate is arranged on one side of the moving plate, the cross section of the bearing plate is U-shaped, the bearing plate is provided with a sliding block and two mutually parallel rails, one side of the sliding block is fixedly connected with the output end of the moving cylinder, in the working state, the moving cylinder pushes the sliding block to move back and forth, the moving direction of the sliding block is vertical to the length direction of the track, the track is provided with a driving block, four moving wheels are arranged below the driving block, a rotating shaft is arranged between the two moving wheels at one end of the driving block, a driven gear is arranged on the rotating shaft, a moving motor is arranged at the lower end of the driving block, and a driving gear meshed with the driven gear is arranged at the output end of the moving motor.

In a preferred embodiment of the invention, the welding assembly comprises a welding head and a welding machine, the welding machine is positioned beside the lifting platform and is connected with the welding head through a wire, the upper end of the driving block is provided with a mounting block, the lower end of the mounting block is rotatably connected with the driving block, the welding head is mounted at the upper end of the mounting block, the lower end of the driving block is provided with a welding motor, and the output end of the welding motor penetrates through the driving block and is fixedly connected with the lower end of the mounting block.

The invention provides a cold welding device of an aluminum alloy window through improvement, compared with the prior art, the cold welding device has the following improvements and advantages:

(1) through the cooperation work of two adjusting part, lift platform and lead screw slip table can make the device be applicable to the welding process of multiple size aluminum alloy window frame.

(2) Two adjacent aluminum alloy materials can be fixed through the cooperation work of adjusting part and locating component for the edge of two aluminum alloy materials aligns, and can not take place the skew in welding process, can process aluminum alloy window frame welded speed.

(3) The device simple structure, occupation space is less and low cost, is applicable to the use of little shop.

Drawings

The invention is further explained below with reference to the figures and examples:

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a partial perspective view of the first embodiment of the present invention;

FIG. 3 is an enlarged view taken at A in FIG. 2;

FIG. 4 is a side view of FIG. 2;

FIG. 5 is a partial perspective view of the second embodiment of the present invention;

FIG. 6 is a third schematic view of a partial perspective structure of the present invention;

FIG. 7 is a fourth schematic view of a partial perspective structure of the present invention;

description of reference numerals: a rotating mechanism 1, a mounting table 1a, a rotating motor 1b, a first rotating disc 1c, a second rotating disc 1d, a sliding rail 1d1, a sliding chute 1d2, a sliding chute 1d3, a connecting block 1e, a positioning mechanism 2, a positioning assembly 2a, a positioning plate 2a1, a positioning cylinder 2a2, a positioning sheet 2a3, a gasket 2a4, an adjusting mechanism 3, a driving component 3a, a driving motor 3a1, a driving rod 3a2, a fixed block 3a3, a connecting strip 3a4, an adjusting component 3b, a discharging block 3b1, a discharging groove 3b2, a connecting sheet 3b3, a roller 3b4, a welding mechanism 4, a welding component 4a, a welding head 4a1, a mounting block 4a1, a welding motor 4a1, a moving component 4b, a1, a moving plate 364 b1, a moving cylinder 4b1, a bearing plate 4b1, a track 4b1, a moving plate 1, a driving wheel 364 b, a driving wheel 1, a driving wheel 364 b1, a moving motor 4b10, a displacement assembly 4c, a lifting platform 4c1 and a screw rod sliding table 4c 2.

Detailed Description

The present invention will be described in detail with reference to fig. 1 to 7, and the technical solutions in the embodiments of the present invention will be clearly and completely described, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all 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 invention provides a cold welding device of an aluminum alloy window through improvement, as shown in figures 1-7, the cold welding device comprises a rotating mechanism 1, a positioning mechanism 2, an adjusting mechanism 3 and a welding mechanism 4, wherein the positioning mechanism 2 and the adjusting mechanism 3 are both fixedly arranged on the rotating mechanism 1, the welding mechanism 4 is arranged beside the rotating mechanism 1, the adjusting mechanism 3 comprises two adjusting components, each adjusting component comprises a driving part 3a and two adjusting parts 3b, the two adjusting parts 3b are both fixedly connected with the driving part 3a, the positioning mechanism 2 comprises four positioning components 2a, the four positioning components 2a are respectively arranged on the four adjusting parts 3b, the welding mechanism 4 comprises a welding component 4a, a moving component 4b and a displacement component 4c, the displacement component 4c is arranged beside the rotating mechanism 1, the moving assembly 4b is arranged at the upper end of the displacement assembly 4c, and the welding assembly 4a is fixedly arranged on the moving assembly 4 b; the distance between two adjusting part 3b is adjusted to the size of the aluminum alloy window that drive part 3a made as required, places aluminum alloy window limit on adjusting part and fixes it through locating component 2a, adjusts the distance on welding subassembly 4a to aluminum alloy window limit through displacement subassembly 4c simultaneously, drives welding subassembly 4a and removes and weld two aluminum alloy window frames that link to each other under the work of removal subassembly 4 b.

The rotating mechanism 1 comprises an installation platform 1a, a rotating motor 1b, a first rotating disk 1c and a second rotating disk 1d, the first rotating disk 1c and the second rotating disk 1d are both vertically arranged, a connecting block 1e for connecting the first rotating disk 1c and the second rotating disk 1d is arranged between the first rotating disk 1c and the second rotating disk 1d, the rotating motor 1b is horizontally arranged on the installation platform 1a, and the output end of the rotating motor 1b is fixedly connected with the first rotating disk 1 c; the first rotating disk 1c and the second rotating disk 1d are driven to synchronously rotate through the rotating motor 1b, so that the adjusting mechanism 3 and the positioning mechanism 2 which are arranged on the second rotating disk 1d are driven to rotate.

One side of the second rotating disk 1d is provided with four sliding rails 1d1 arranged in a groined shape, two ends of each sliding rail 1d1 are provided with four sliding grooves 1d2, the second rotating disk 1d is provided with four sliding groove groups distributed in a rectangular shape, and each sliding groove group comprises two sliding grooves 1d3 which are parallel to each other; the slide groove 1d3 is used in cooperation with the slide groove 1d2 for cooperating with the driving member 3a and the adjusting member 3b so that the position of the adjusting member 3b can be changed.

Each adjusting component 3b comprises a discharging block 3b1, a discharging groove 3b2 is arranged on one side of the discharging block 3b1, four connecting pieces 3b3 are arranged at two ends of the other side of the discharging block 3b1, and a roller 3b4 in rolling fit with the sliding groove 1d2 is arranged on one side of each connecting piece 3b 3; the friction between the tapblock 3b1 and the slide rail 1d1 can be reduced by the rolling engagement of the slide groove 1d2 and the roller 3b 4.

Each driving part 3a comprises a driving motor 3a1 and a driving rod 3a2, the driving rod 3a2 penetrates through the connecting block 1e, the driving motor 3a1 is installed between the first rotating disk 1c and the second rotating disk 1d, the output end of the driving motor 3a1 is fixedly connected with the driving rod 3a2, two ends of the driving rod 3a2 are respectively provided with a first thread and a second thread, the thread pitches of the first thread and the second thread are the same, and the spiral directions are opposite, two ends of the driving rod 3a2 are respectively provided with a fixed block 3a3, two fixed blocks 3a3 are respectively in threaded fit with the first thread and the second thread, one side of the fixed block 3a3 is provided with two connecting strips 3a4 in sliding fit with the sliding grooves 1d3, and one end of each connecting strip 3a4 is fixedly connected with the emptying block 3b 1; the driving rod 3a2 is driven by the driving motor 3a1 to rotate, the fixing block 3a3 in threaded fit with the driving rod 3a2 moves along the length direction of the driving rod 3a2, and the two fixing blocks 3a3 move towards or away from each other synchronously due to the same pitch and opposite spiral directions of the first thread and the second thread.

Each positioning assembly 2a comprises two positioning plates 2a1 and two positioning cylinders 2a2, the cross sections of the two positioning plates 2a1 are L-shaped, the two positioning plates 2a1 are respectively installed at two ends of a discharging block 3b1, the two positioning cylinders 2a2 are respectively fixedly connected with the two positioning plates 2a1, the output ends of the two positioning cylinders 2a2 penetrate through the discharging block 3b1 and extend into a discharging groove 3b2, the output ends of the two positioning cylinders 2a2 are respectively provided with a positioning piece 2a3, and one side of each positioning piece 2a3 is provided with a gasket 2a 4; when the positioning cylinder 2a2 works, the positioning piece 2a3 presses the aluminum alloy window edge, and the gasket 2a4 is made of rubber and used for protecting the aluminum alloy window edge.

The displacement assembly 4c comprises a lifting platform 4c1 and a screw rod sliding table 4c2, the lifting platform 4c1 is located beside the rotating mechanism 1, and the screw rod sliding table 4c2 is horizontally arranged at the upper end of the lifting platform 4c 1; the lifting platform 4c1 is used for adjusting the horizontal height of the welding assembly 4a, and the screw rod sliding table 4c2 is used for adjusting the horizontal distance from the welding assembly 4a to the rotating assembly.

The moving assembly 4b comprises a moving plate 4b1, a moving cylinder 4b2 and a supporting plate 4b3, the moving plate 4b1 is fixedly arranged on a sliding block of a screw rod sliding table 4c2, the moving cylinder 4b2 is horizontally arranged at the upper end of a moving plate 4b1, the supporting plate 4b3 is arranged on one side of the moving plate 4b1, the cross section of the supporting plate 4b3 is U-shaped, the supporting plate 4b3 is provided with a sliding block 4b5 and two mutually parallel rails 4b4, one side of the sliding block 4b5 is fixedly connected with the output end of the moving cylinder 4b2, in an operating state, the moving cylinder 4b2 pushes the sliding block to move back and forth, the moving direction of the sliding block is vertical to the length direction of the rails 4b4, the rails 4b4 are provided with driving blocks 4b6, four moving wheels 4b7 are arranged below the driving block 4b6, and two moving wheels 4b7 positioned at one end of the driving block 4b6 are, a driven gear is arranged on the rotating shaft, a moving motor 4b10 is arranged at the lower end of the driving block 4b6, and a driving gear 4b9 meshed with the driven gear is arranged at the output end of the moving motor 4b 10; the movable motor 4b10 can drive the movable wheel 4b7 to rotate, so that the driving block 4b6 can move on the track 4b4, the upper end structure of the sliding block 4b5 is the same as that of the upper end of the track 4b4, the driving block 4b6 can move from one track 4b4 to the sliding block 4b5, the sliding block 4b5 is pushed to one end of the other track 4b4 through the operation of the movable air cylinder 4b2, and the driving block 4b6 can move to the other track 4b4, so that the welding component 4a on the driving block 4b6 can weld three sides of the connection part of the aluminum alloy window frame.

The welding assembly 4a comprises a welding head 4a1 and a welding machine 4a2, the welding machine 4a2 is located beside the lifting platform 4c1, the welding machine 4a2 is connected with the welding head 4a1 through an electric wire, the upper end of the driving block 4b6 is provided with a mounting block 4a3, the lower end of the mounting block 4a3 is rotatably connected with a driving block 4b6, the welding head 4a1 is mounted at the upper end of the mounting block 4a3, the lower end of the driving block 4b6 is provided with a welding motor 4a4, and the output end of the welding motor 4a4 penetrates through the driving block 4b6 and is fixedly connected with the lower end of the mounting block 4a 3; the welding head 4a1 and the mounting block 4a3 can be connected by clamping or screws by the welding head 4a1 being in contact alignment with the joint of the aluminum alloy window frame for welding, so that the position of the welding head 4a1 can be adjusted conveniently.

The working principle of the invention is as follows: when the aluminum alloy welding machine is used, the positions of two adjusting assemblies are adjusted according to the size of an aluminum alloy window to be welded, the height of a lifting platform 4c1 is adjusted, then aluminum alloy materials are placed in two adjacent material discharging grooves 3b2, a positioning cylinder 2a2 works to enable a positioning sheet 2a3 to press the aluminum alloy materials tightly, a rotating motor 1b drives a first rotating disk 1c and a second rotating disk 1d to rotate 45 degrees, the joint of the two aluminum alloy materials is located beside the welding assembly 4a, the welding assembly 4a is driven to move to the welding position through a screw rod sliding table 4c2, a driving block 4b10 works to drive a sliding block 4b6 to move to the sliding block 4b5 from one rail 4b4, the sliding block 4b5 is driven to one end of the other rail 4b4 through a moving cylinder 4b2, the driving block 4b6 can move to the other rail 4b4 from the sliding block 4b5, meanwhile, the welding motor 4a4 can drive the welding head 4a1 to rotate, so that the joint of the two aluminum alloy materials is welded, the rotating motor 1b drives the first rotating disk 1c and the second rotating disk 1d to rotate for 45 degrees, another aluminum alloy material is placed in the uppermost feeding groove 3b2, and the rotating motor 1b drives the first rotating disk 1c and the second rotating disk 1d to rotate for 45 degrees and repeats the process until the welding of the aluminum alloy window frame is completed.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. The working method of the cold welding device of the aluminum alloy window is characterized in that: the cold welding device of the aluminum alloy window comprises a rotating mechanism (1), a positioning mechanism (2), an adjusting mechanism (3) and a welding mechanism (4), wherein the positioning mechanism (2) and the adjusting mechanism (3) are fixedly arranged on the rotating mechanism (1), the welding mechanism (4) is positioned beside the rotating mechanism (1), the adjusting mechanism (3) comprises two adjusting components, each adjusting component comprises a driving part (3 a) and two adjusting parts (3 b), the two adjusting parts (3 b) are fixedly connected with the driving part (3 a), the positioning mechanism (2) comprises four positioning components (2 a), the four positioning components (2 a) are respectively arranged on the four adjusting parts (3 b), the welding mechanism (4) comprises a welding component (4 a), a moving component (4 b) and a displacement component (4 c), the displacement assembly (4 c) is located beside the rotating mechanism (1), the moving assembly (4 b) is installed at the upper end of the displacement assembly (4 c), and the welding assembly (4 a) is fixedly installed on the moving assembly (4 b); the rotating mechanism (1) comprises an installation platform (1 a), a rotating motor (1 b), a first rotating disk (1 c) and a second rotating disk (1 d), the first rotating disk (1 c) and the second rotating disk (1 d) are both vertically arranged, a connecting block (1 e) for connecting the first rotating disk (1 c) and the second rotating disk (1 d) is arranged between the first rotating disk (1 c) and the second rotating disk (1 d), the rotating motor (1 b) is horizontally arranged on the installation platform (1 a), and the output end of the rotating motor (1 b) is fixedly connected with the first rotating disk (1 c); four sliding rails (1 d 1) arranged in a groined shape are arranged on one side of the second rotating disk (1 d), two ends of each sliding rail (1 d 1) are respectively provided with four sliding grooves (1 d 2), four sliding groove groups distributed in a rectangular shape are arranged on the second rotating disk (1 d), and each sliding groove group comprises two sliding grooves (1 d 3) which are parallel to each other; each adjusting part (3 b) comprises a discharging block (3 b 1), a discharging groove (3 b 2) is formed in one side of the discharging block (3 b 1), four connecting pieces (3 b 3) are arranged at two ends of the other side of the discharging block (3 b 1), and a roller (3 b 4) in rolling fit with the sliding groove (1 d 2) is arranged on one side of each connecting piece (3 b 3); the working method comprises the following steps: the positions of two adjusting assemblies are adjusted according to the size of an aluminum alloy window to be welded, the height of a lifting platform (4 c 1) is adjusted at the same time, then aluminum alloy materials are placed in two adjacent discharging grooves (3 b 2), a positioning cylinder (2 a 2) works to enable a positioning sheet (2 a 3) to press the aluminum alloy materials tightly, a rotating motor (1 b) drives a first rotating disk (1 c) and a second rotating disk (1 d) to rotate for 45 degrees, so that the joint of the two aluminum alloy materials is located beside a welding assembly (4 a), the welding assembly (4 a) is driven to move to the welding position through a screw rod sliding table (4 c 2), a moving motor (4 b 10) works to drive a driving block (4 b 6) to move to a sliding block (4 b 5) from one rail (4 b 4), and the sliding block (4 b 5) is pushed to one end of the other rail (4 b 4) through a moving cylinder (4 b 2), the driving block (4 b 6) can move from the sliding block (4 b 5) to another track (4 b 4), meanwhile, the welding head (4 a1) can be driven to turn by the operation of the welding motor (4 a4), so that the joint of the two aluminum alloy materials is welded, then the rotating motor (1 b) drives the first rotating disk (1 c) and the second rotating disk (1 d) to rotate for 45 degrees, another aluminum alloy material is placed in the uppermost discharging groove (3 b 2), and the rotating motor (1 b) drives the first rotating disk (1 c) and the second rotating disk (1 d) to rotate for 45 degrees and the steps are repeated until the welding of the aluminum alloy window frame is completed.

2. The method of operating a cold welding apparatus for an aluminum alloy window according to claim 1, wherein: each of the driving parts (3 a) includes a driving motor (3 a1) and a driving lever (3 a 2), the driving rod (3 a 2) penetrates through the connecting block (1 e), the driving motor (3 a1) is installed between the first rotating disk (1 c) and the second rotating disk (1 d), the output end of the driving motor (3 a1) is fixedly connected with the driving rod (3 a 2), the two ends of the driving rod (3 a 2) are respectively provided with a first thread and a second thread, the thread pitch of the first thread and the thread pitch of the second thread are the same, the thread directions are opposite, both ends of the driving rod (3 a 2) are provided with fixing blocks (3 a 3), the two fixing blocks (3 a 3) are respectively in threaded fit with the first thread and the second thread, one side of the fixed block (3 a 3) is provided with two connecting strips (3 a4) which are in sliding fit with the sliding groove (1 d 3), one end of each connecting strip (3 a4) is fixedly connected with the discharging block (3 b 1).

3. The method of operating a cold welding apparatus for an aluminum alloy window according to claim 2, wherein: every locating component (2 a) all includes two locating plates (2 a1) and two location cylinders (2 a 2), two the cross section of locating plate (2 a1) all is the both ends at bleeder (3 b 1) respectively in L type and two locating plates (2 a1), two location cylinders (2 a 2) all run through bleeder (3 b 1) to extending in bleeder groove (3 b 2) with two locating plates (2 a1) fixed connection and two output ends of locating cylinder (2 a 2) respectively, all be equipped with locating piece (2 a 3) on the output of two location cylinders (2 a 2), one side of locating piece (2 a 3) all is equipped with gasket (2 a 4).

4. The method of operating a cold welding apparatus for an aluminum alloy window according to claim 1, wherein: displacement subassembly (4 c) include lift platform (4 c 1) and lead screw slip table (4 c 2), lift platform (4 c 1) are located the side of rotary mechanism (1), lead screw slip table (4 c 2) are the upper end of level setting at lift platform (4 c 1).

5. A method of operating a cold welding apparatus for an aluminum alloy window according to claim 3, wherein: the moving assembly (4 b) comprises a moving plate (4 b 1), a moving cylinder (4 b 2) and a bearing plate (4 b 3), the moving plate (4 b 1) is fixedly installed on a sliding block of a screw rod sliding table (4 c 2), the moving cylinder (4 b 2) is horizontally arranged at the upper end of the moving plate (4 b 1), the bearing plate (4 b 3) is installed on one side of the moving plate (4 b 1) and the cross section of the bearing plate (4 b 3) is U-shaped, a sliding block (4 b 5) and two mutually parallel tracks (4 b 4) are arranged on the bearing plate (4 b 3), one side of the sliding block (4 b 5) is fixedly connected with the output end of the moving cylinder (4 b 2), in the working state, the moving cylinder (4 b 2) pushes the sliding block to move back and forth, the moving direction of the sliding block is perpendicular to the length direction of the track (4 b 4), and a driving block (4 b 6) is arranged on the track (4 b 4), four moving wheels (4 b 7) are arranged below the driving block (4 b 6), a rotating shaft is arranged between the two moving wheels (4 b 7) positioned at one end of the driving block (4 b 6), a driven gear is arranged on the rotating shaft, a moving motor (4 b 10) is arranged at the lower end of the driving block (4 b 6), and a driving gear (4 b 9) meshed with the driven gear is arranged at the output end of the moving motor (4 b 10).

6. The method of operating a cold welding apparatus for an aluminum alloy window according to claim 4, wherein: the welding assembly (4 a) comprises a welding head (4 a1) and a welding machine (4 a 2), wherein the welding machine (4 a 2) is located beside the lifting platform (4 c 1), the welding machine (4 a 2) is connected with the welding head (4 a1) through an electric wire, the upper end of the driving block (4 b 6) is provided with a mounting block (4 a 3), the lower end of the mounting block (4 a 3) is rotatably connected with a driving block (4 b 6), the welding head (4 a1) is mounted at the upper end of the mounting block (4 a 3), the lower end of the driving block (4 b 6) is provided with a welding motor (4 a4), and the output end of the welding motor (4 a4) penetrates through the driving block (4 b 6) and is fixedly connected with the lower end of the mounting block (4 a 3).