CN221087018U - Corner combining machine for processing aluminum alloy doors and windows - Google Patents

Abstract

The utility model discloses a corner combining machine for processing aluminum alloy doors and windows, which comprises a bottom plate and the aluminum alloy doors and windows placed on the bottom plate, wherein the bottom plate is symmetrically provided with first sliding blocks for carrying out auxiliary multi-angle processing on the aluminum alloy doors and windows, the first sliding blocks are provided with electric compression rods for processing the aluminum alloy doors and windows, the top of the bottom plate is provided with second sliding rails for processing the aluminum alloy doors and windows with different thicknesses, one side of the angle plate is provided with a rotating motor for flexible sliding.

Description

Corner combining machine for processing aluminum alloy doors and windows

Technical Field

The utility model relates to the technical field of corner combining machines, in particular to a corner combining machine for processing an aluminum alloy door and window.

Background

At present, the living standard of people is continuously improved, the types of doors and windows and derived products thereof are continuously increased, the grades are gradually increased, the doors and windows are divided into enclosure members or separation members according to different positions of the doors and windows, the doors and windows are important components in a building enclosure structure system, the aluminum alloy doors and windows have the advantages of no deformation, no color change, no damage, space saving, flexible collocation and simplicity and attractiveness, the corner assembling machine is special equipment for producing high-grade bridge-cut-off aluminum alloy doors and windows, in actual life, the aluminum alloy doors and windows are customized for houses with different types due to different types of rooms, when the corner assembling machine is used for processing the aluminum alloy doors and windows, the fixed aluminum alloy parts are compressed and formed through fixed electric compression rods generally, so that the processing effect is achieved, but once the aluminum alloy doors and windows with multiple angles are required to be formed, the existing processing device cannot flexibly change the overall processing angle of the aluminum alloy doors and windows, so that the processing efficiency of the overall aluminum alloy is influenced, and the suitability and the universality of the overall device are reduced.

Therefore, we design a corner combining machine for processing aluminum alloy doors and windows.

Disclosure of utility model

The utility model aims to solve the problem that multi-angle machining cannot be performed, and provides an angle combining machine for aluminum alloy door and window machining.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides an aluminum alloy door and window processing is with group angle machine, includes the bottom plate and places the aluminum alloy door and window on the bottom plate, the bottom plate symmetry is equipped with the first slider that is used for carrying out supplementary multi-angle processing to aluminum alloy door and window, be equipped with the electronic compression pole that is used for processing to aluminum alloy door and window on the first slider, the bottom plate top is equipped with the second slide rail that is used for processing to aluminum alloy door and window of different thickness, the symmetry is equipped with the angle board that is used for carrying out the angle regulation to aluminum alloy door and window on the second slide rail, angle board one side is equipped with the rotating electrical machines that is used for nimble gliding.

Preferably, a first sliding rail is arranged at the top of the bottom plate, a control panel is arranged on the first sliding block, and the control panel slides in the first sliding rail through the first sliding block.

Preferably, the output end of the control panel is connected with an electric compression rod, a rotating shaft and a pressing plate are arranged at the top end of the electric compression rod, and the pressing plate is connected with the electric compression rod through the rotating shaft.

Preferably, a sliding motor, a first screw rod and a second sliding block are arranged in the second sliding rail, the output end of the sliding motor is connected with the first screw rod, a hinge is arranged on the second sliding block, and the hinge slides in the second sliding rail through the second sliding block and the first screw rod.

Preferably, a third sliding rail is arranged at the top of the second sliding block, the angle plate rotates on one side of the third sliding rail through a hinge, and an auxiliary groove is arranged on one side of the angle plate.

Preferably, a third sliding block, an auxiliary block, a rotating shaft and a fourth sliding rail are arranged in the auxiliary groove, the auxiliary block is connected with the third sliding block through the rotating shaft, and the third sliding block slides in the auxiliary groove through the fourth sliding rail.

Preferably, the rotating motor is fixedly arranged at the top of the second sliding block, a second screw rod is arranged at the output end of the rotating motor, and the second screw rod penetrates through the auxiliary block.

The beneficial effects of the utility model are as follows:

1. According to the utility model, when the angle of the aluminum alloy door and window is required to be adjusted through the electric telescopic rod, the angle plate and other parts, the rotating motor drives the second screw rod to rotate, so that the position of the angle plate is changed, the sliding angle is changed through the electric telescopic rod on one side, the aluminum alloy door and window is processed, the problem that the whole processing angle of the aluminum alloy door and window cannot be flexibly changed is avoided, the processing efficiency of the whole aluminum alloy is influenced, and the suitability and the universality of the whole device are reduced.

2. According to the utility model, when the aluminum alloy doors and windows with different thicknesses are required to be processed through the sliding motor, the position of the second sliding block is flexibly changed through the sliding motor, so that the suitability of the whole device is improved, and the situation that the aluminum alloy doors and windows are too thick to be placed on the whole device for processing is avoided.

Drawings

FIG. 1 is a two isometric view of an angle assembling machine for processing aluminum alloy doors and windows;

fig. 2 is a front view of an angle assembling machine for processing aluminum alloy doors and windows;

FIG. 3 is a schematic diagram of a corner combining machine for processing aluminum alloy doors and windows according to the present utility model;

fig. 4 is a detailed schematic diagram of a corner combining machine for processing aluminum alloy doors and windows.

In the figure: 1. a bottom plate; 2. a first slide rail; 3. a first slider; 4. a control panel; 5. an electric compression rod; 6. a rotating shaft; 7. a pressing plate; 8. a second slide rail; 9. a slide motor; 10. a first screw rod; 11. a second slider; 12. an angle plate; 13. a hinge; 14. a rotating electric machine; 15. a second screw rod; 16. a third slide rail; 17. an auxiliary groove; 18. a third slider; 19. and an auxiliary block.

Detailed Description

Referring to fig. 1-4, an angle assembling machine for processing aluminum alloy doors and windows comprises a bottom plate 1 and aluminum alloy doors and windows arranged on the bottom plate 1, wherein the angle assembling machine is used for assisting in arranging the aluminum alloy doors and windows through a box body 1.

The bottom plate 1 symmetry is equipped with and is used for carrying out the first slider 3 of supplementary multi-angle processing to aluminum alloy door and window, and bottom plate 1 top is equipped with first slide rail 2 for carry out the supplementary slip through second slide rail 2, be equipped with control panel 4 on the first slider 3, control panel 4 slides in first slide rail 2 through first slider 3, because supplementary follow-up part carries out the multi-angle and processes aluminum alloy door and window.

Be equipped with the electronic compression pole 5 that is used for processing aluminum alloy door and window on the first slider 3, control panel 4 output links to each other with electronic compression pole 5 for control electronic compression pole 5 through control panel 4, electronic compression pole 5 top is equipped with pivot 6 and clamp plate 7, and clamp plate 7 links to each other with electronic compression pole 5 through pivot 6, when processing aluminum alloy door and window, through clamp plate 7 and the nimble adaptation processing angle of pivot 6, and then reach the effect of nimble adaptation.

The bottom plate 1 top is equipped with the second slide rail 8 that is used for processing the aluminum alloy door and window of different thickness, be equipped with slide motor 9 in the second slide rail 8, first lead screw 10 and second slider 11, slide motor 9 output links to each other with first lead screw 10, be used for carrying out drive control to first lead screw 10 through slide motor 9, be equipped with hinge 13 on the second slider 11, be used for assisting follow-up part to rotate, hinge 13 slides in second slide rail 8 through second slider 11 and first lead screw 10, when needs are processed the aluminum alloy door and window of different thickness, change the position of second slider 11 through slide motor 9 is nimble, and then improve whole device's suitability, avoid aluminum alloy door and window too thick, can't place and process on whole device.

The angle plate 12 used for adjusting the machining angle of the aluminum alloy door and window is symmetrically arranged on the second sliding rail 8, the third sliding rail 16 is arranged at the top of the second sliding block 11, the angle plate 12 rotates on one side of the third sliding rail 16 through the hinge 13 and is used for forming an angle through connection of the two angle plates 12, the aluminum alloy door and window is further assisted in angle adjustment and forming, and the auxiliary groove 17 is formed in one side of the angle plate 12 and used for assisting subsequent parts to be placed.

The auxiliary groove 17 is internally provided with a third sliding block 18, an auxiliary block 19, a rotating shaft and a fourth sliding rail, the auxiliary block 19 is connected with the third sliding block 18 through the rotating shaft and used for flexibly adapting through the rotating shaft when the auxiliary block 19 flexibly slides, and the third sliding block 18 slides in the auxiliary groove 17 through the fourth sliding rail and is used for controlling the angle plate 12 through the third sliding block 18 and the auxiliary block 19 when the subsequent part drives.

The angle board 12 one side is equipped with the rotating electrical machines 14 that are used for nimble gliding, the fixed setting of rotating electrical machines 14 is at second slider 11 top for drive through rotating electrical machines 14, the rotating electrical machines 14 output is equipped with second lead screw 15, be used for driving second lead screw 15 through rotating electrical machines 14, second lead screw 15 runs through auxiliary block 19, be used for the slip of the rotatory control auxiliary block 19 through second lead screw 15, and then control the position of angle board 12 through the slip of auxiliary block 19, avoid unable nimble whole processing angle that changes aluminum alloy door and window, and then influence the machining efficiency of whole aluminum alloy, reduce whole device's suitability and commonality.

The working principle of the utility model is as follows: when needing to process the aluminum alloy door and window of different angles, through the slip of first slider 3 and first slide rail 2, change the processing angle of top control panel 4 and electronic compression pole 5 in a flexible way, rethread clamp plate 7 and pivot 6 adapt the processing angle in a flexible way, rotate through rotating electrical machines 14 control second lead screw 15, and then drive auxiliary block 19 through the rotation of second lead screw 15, and then control the position of angle board 12 through the slip of auxiliary block 19, reach the effect of angle processing.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (7)

1. The utility model provides an aluminum alloy door and window processing is with group angle machine, includes bottom plate (1) and places aluminum alloy door and window on bottom plate (1), its characterized in that, bottom plate (1) symmetry is equipped with and is used for carrying out first slider (3) of supplementary multi-angle processing to aluminum alloy door and window, be equipped with on first slider (3) and be used for carrying out electronic compression pole (5) of processing to aluminum alloy door and window, bottom plate (1) top is equipped with second slide rail (8) that are used for carrying out processing to aluminum alloy door and window of different thickness, the symmetry is equipped with on second slide rail (8) and is used for carrying out angle regulation's angle board (12) to aluminum alloy door and window, angle board (12) one side is equipped with rotary motor (14) that are used for nimble slip.

2. The corner combining machine for aluminum alloy door and window machining according to claim 1, wherein a first sliding rail (2) is arranged at the top of the bottom plate (1), a control panel (4) is arranged on the first sliding block (3), and the control panel (4) slides in the first sliding rail (2) through the first sliding block (3).

3. The corner combining machine for aluminum alloy door and window machining according to claim 2, wherein the output end of the control panel (4) is connected with the electric compression rod (5), a rotating shaft (6) and a pressing plate (7) are arranged at the top end of the electric compression rod (5), and the pressing plate (7) is connected with the electric compression rod (5) through the rotating shaft (6).

4. The corner combining machine for aluminum alloy door and window machining according to claim 1, wherein a sliding motor (9), a first screw rod (10) and a second sliding block (11) are arranged in the second sliding rail (8), the output end of the sliding motor (9) is connected with the first screw rod (10), a hinge (13) is arranged on the second sliding block (11), and the hinge (13) slides in the second sliding rail (8) through the second sliding block (11) and the first screw rod (10).

5. The corner combining machine for aluminum alloy door and window machining according to claim 4, wherein a third sliding rail (16) is arranged at the top of the second sliding block (11), the angle plate (12) rotates on one side of the third sliding rail (16) through a hinge (13), and an auxiliary groove (17) is formed on one side of the angle plate (12).

6. The corner combining machine for aluminum alloy door and window machining according to claim 5, wherein a third sliding block (18), an auxiliary block (19), a rotating shaft and a fourth sliding rail are arranged in the auxiliary groove (17), the auxiliary block (19) is connected with the third sliding block (18) through the rotating shaft, and the third sliding block (18) slides in the auxiliary groove (17) through the fourth sliding rail.

7. The corner combining machine for aluminum alloy door and window machining according to claim 6, wherein the rotating motor (14) is fixedly arranged at the top of the second sliding block (11), a second screw rod (15) is arranged at the output end of the rotating motor (14), and the second screw rod (15) penetrates through the auxiliary block (19).