阅读说明：本技术 一种铝合金窗户加工工艺 (Aluminum alloy window processing technology ) 是由 不公告发明人 于 2021-09-13 设计创作，主要内容包括：本发明涉及铝合金窗户领域,尤其是涉及一种铝合金窗户加工工艺。其配合使用了一种铝合金窗户加工设备,该设备包括四个设立在地面上的第一支撑板,所述第一支撑板之间设有加工箱,所述第一支撑板上设有铝合金窗户传送支撑装置,所述加工箱内底部设有铝合金窗户弯曲度检测筛选装置,所述加工箱内顶部两侧对称设有铝合金窗户固定压直装置,所述铝合金窗户固定压直装置之间设有铝合金窗户切割装置。本发明具有在对铝合金窗户加工中可以自动筛选出不符合要求的铝合金杆,铝合金杆弯曲角度越大压紧部件压下数量越多在固定铝合金杆的同时更好地将小弯曲杆压直,以45度角方向切割铝合金窗户提高生产效率降低工人劳动强度的效果。(The invention relates to the field of aluminum alloy windows, in particular to a processing technology of an aluminum alloy window. The aluminum alloy window processing equipment is matched with the aluminum alloy window processing equipment, the aluminum alloy window processing equipment comprises four first supporting plates arranged on the ground, a processing box is arranged between the first supporting plates, an aluminum alloy window conveying and supporting device is arranged on the first supporting plates, an aluminum alloy window curvature detecting and screening device is arranged at the bottom in the processing box, aluminum alloy window fixing and straightening devices are symmetrically arranged at the two sides of the top in the processing box, and an aluminum alloy window cutting device is arranged between the aluminum alloy window fixing and straightening devices. The invention has the effects that aluminum alloy rods which do not meet the requirements can be automatically screened out in the process of processing the aluminum alloy window, the larger the bending angle of the aluminum alloy rods is, the more the pressing quantity of the pressing parts is, the smaller bending rods are pressed to be straightened better while the aluminum alloy rods are fixed, and the aluminum alloy window is cut in the 45-degree angle direction, so that the production efficiency is improved, and the labor intensity of workers is reduced.)

1. The utility model provides an aluminum alloy window processing technology, its characterized in that, its cooperation has used an aluminum alloy window processing equipment, and this equipment includes that four establish subaerial first backup pad (101), be equipped with between first backup pad (101) and process case (102), be equipped with aluminum alloy window conveying strutting arrangement (1) on first backup pad (101), the bottom is equipped with aluminum alloy window crookedness and detects sieving mechanism (2) in processing case (102), top bilateral symmetry is equipped with fixed device (3) of straightening of aluminum alloy window in processing case (102), be equipped with aluminum alloy window cutting device (4) between fixed device (3) of straightening of aluminum alloy window.

2. The aluminum alloy window processing technology according to claim 1, wherein the aluminum alloy window conveying and supporting device (1) further comprises two second supporting plates (104) symmetrically arranged at the bottom of the processing box (102), a third supporting plate (105) is arranged between each first supporting plate (101) and the processing box (102), a conveying belt (103) is symmetrically arranged between the third supporting plates (105) at two sides of the processing box (102), a waste rod groove (106) is arranged in the processing box (102) and is parallel to one side of the conveying belt (103), and a waste chip groove (107) is arranged below the aluminum alloy window cutting device (4) in the processing box (102).

3. The aluminum alloy window processing technology according to claim 2, wherein the aluminum alloy window bending degree detection screening device (2) comprises first hydraulic cavities (201) formed in the upper end of each second supporting plate (104), first hydraulic rods (202) are arranged in each first hydraulic cavity (201), a first spring (203) is arranged between each first hydraulic rod (202) and the first hydraulic cavity (201), two fourth supporting plates (204) are symmetrically arranged on the upper end of each first hydraulic rod (202) in parallel to the conveying belt (103), rotating shafts (205) are arranged between the fourth supporting plates (204), rollers (206) are arranged on the rotating shafts (205), and first oil passages (207) are arranged at the bottoms of the first hydraulic cavities (201).

4. The processing technology of the aluminum alloy window according to claim 3, wherein a second oil path (208) is arranged on one side, close to the discharge end, of the first oil path (207), a second hydraulic cavity (209) is arranged at the tail end of the second oil path (208), the second hydraulic cavity (209) is located on the first oil path (207) close to the feed end, a first slider (210) is arranged in the second hydraulic cavity (209), a third hydraulic cavity (211) is connected to the tail end of the first oil path (207), a second slider (212) is arranged in the third hydraulic cavity (211), second springs (213) are symmetrically arranged on two sides between the second slider (212) and the third hydraulic cavity (211), two third oil paths (214) are symmetrically arranged on the left side and the right side of the inner side of the third hydraulic cavity (211), and a fourth hydraulic cavity (215) is arranged at the other end of each third oil path (214), a third slider (216) is arranged in each fourth hydraulic cavity (215), a third spring (217) is connected to one side, far away from the third oil path (214), of each third slider (216) and the fourth hydraulic cavity (215), a first switch (218) is arranged on one side, far away from the third oil path (214), of each fourth hydraulic cavity (215), a fourth oil path (219) is coaxially arranged on one inward side of each fourth hydraulic cavity (215) and the third oil path (214), a fifth hydraulic cavity (220) is arranged on the other side of each fourth oil path (219), and a second hydraulic rod (221) is arranged in each fifth hydraulic cavity (220).

5. The aluminum alloy window processing technology according to claim 4, wherein fifth hydraulic chambers (222) are symmetrically arranged on the top of the third hydraulic chamber (211) from left to right, a fourth slider (223) is arranged in each fifth hydraulic chamber (222), a fourth spring (224) is arranged between each fifth hydraulic chamber (222) and the fourth slider (223), a sixth hydraulic chamber (226) is arranged between the fifth hydraulic chambers (222), a fifth oil path (225) is arranged between each fifth hydraulic chamber (222) and the sixth hydraulic chamber (226), a sixth oil path (228) is arranged on the sixth hydraulic chamber (226) and is horizontally vertical to the fifth oil path (225), and a baffle (227) is arranged at the sixth oil path (228) on the second slider (212).

6. The aluminum alloy window processing technology according to claim 5, wherein the aluminum alloy window fixing and straightening device (3) comprises a fifth support plate (309) arranged at the top of the processing box (102), each fifth support plate (309) is internally provided with a plurality of pressing components (301), each pressing component (301) comprises a seventh hydraulic cavity (302) arranged on the fifth support plate (309), each seventh hydraulic cavity (302) is internally provided with a third hydraulic rod (303), each third hydraulic rod (303) is internally provided with a sliding chute (304), each sliding chute (304) is internally provided with a sliding rod (305), a fifth spring (306) is arranged between each sliding rod (305) and the sliding chute (304), the bottom of each sliding chute (304) is provided with a second switch (307), and the tail end of each sixth oil path (228) is connected with the first seventh hydraulic cavity (302), and a seventh oil path (308) is arranged between every two seventh hydraulic cavities (302).

7. The aluminum alloy window processing technology according to claim 6, wherein the aluminum alloy window cutting device (4) comprises a hydraulic tank (401) arranged between a fifth support plate (309) arranged on the top of the processing tank (102), the sixth oil path (228) is arranged on the top of the hydraulic tank (401), the hydraulic tank (401) is provided with a sixth support plate (403), an eighth hydraulic cavity (402) is arranged in the sixth support plate (403), a fourth hydraulic rod (404) is arranged in the eighth hydraulic cavity (402), a servo motor (405) is arranged at the bottom of the fourth hydraulic rod (404), and a blade (406) is arranged at the output end of the servo motor (405).

8. An aluminum alloy window processing technology according to claims 1-7, wherein the aluminum alloy window processing technology comprises the following steps:

s1: aluminum alloy rods are placed on a conveyor belt (103), the conveyor belt (103) sends the aluminum alloy rods into a processing box (102), friction is reduced when the aluminum alloy rods pass through rollers (206), the bending angles of the aluminum alloy rods are different, the rollers (206) are pressed downwards to different degrees, the rollers (206) drive a rotating shaft (205) to press downwards, the rotating shaft (205) drives a fourth supporting plate (204) to press downwards, the fourth supporting plate (204) drives a first hydraulic rod (202) to press downwards, so that hydraulic oil enters a first oil path (207), the hydraulic oil enters a second oil path (208) from the first oil path (207), the first sliding block (210) is opened by pushing of the hydraulic oil, when the bending angle of the aluminum alloy rods is too large, a third hydraulic cavity (211) is communicated with a third oil path (214), the third sliding block (216) touches a first switch (218) to open the fourth oil path (219), and the hydraulic oil once enters a fifth hydraulic cavity (220), the second hydraulic rod (221) pushes the aluminum alloy rod into the waste rod groove (106);

s2: when the bending angle of the aluminum alloy rod is smaller, hydraulic oil in the third hydraulic cavity (211) pushes the fourth slider (223) to enter the sixth hydraulic cavity (226) through the fifth oil path (225), the different bending angles of the aluminum alloy rod drive the baffle (227) to open the sixth oil paths (228) with different sizes, the hydraulic oil enters the seventh hydraulic cavity (302) through the sixth oil path (228), the third hydraulic rod (303) is pushed to move forwards, the third hydraulic rod (303) drives the sliding rod (305) to press the aluminum alloy rod forwards, the pressure is increased until the sliding rod (305) touches the second switch (307) to open the seventh oil path (308), the hydraulic oil enters the next seventh hydraulic cavity (302), and the pressing part (301) is pressed more in quantity when the aluminum alloy rod is fixed and the small bending rod is pressed better when the bending angle of the aluminum alloy rod is larger;

s3: the hydraulic tank (401) pushes the fourth hydraulic rod (404) to move in the sixth supporting plate (403), the fourth hydraulic rod (404) drives the servo motor (405) to move downwards, and the servo motor (405) drives the blade (406) to cut the aluminum alloy rod.

Technical Field

The invention relates to the field of aluminum alloy windows, in particular to a processing technology of an aluminum alloy window.

Background

The aluminum alloy window has the advantages of attractive appearance, sealing and high strength, and is widely applied to the field of constructional engineering. In window processing, the frame of the door window needs to be cut.

Aluminum alloy windows require high sealability, and therefore, aluminum alloys with excessively high degrees of bending cannot be used for processing. The notch of the aluminum alloy window is generally at an angle of 45 degrees, but the conventional cutting is always vertical, and secondary processing is required. The aluminum alloy with too high bending degree can cause unqualified products and waste. Some bending within the allowable range may also cause a certain machining error. Therefore, the aluminum alloy window processing technology is provided for solving the problems, aluminum alloy rods which do not meet the requirements can be automatically screened, and the larger the bending angle of the aluminum alloy rods is, the larger the pressing quantity of pressing parts is, the smaller bending rods can be better straightened while the aluminum alloy rods are fixed.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides an aluminum alloy window processing technology which can automatically screen out aluminum alloy rods which do not meet the requirements in the process of processing an aluminum alloy window, wherein the larger the bending angle of the aluminum alloy rods, the larger the pressing quantity of pressing parts, the better the small bending rods are pressed to straighten while fixing the aluminum alloy rods, and the aluminum alloy window is cut in the 45-degree angle direction.

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

the utility model provides an aluminum alloy window processing technology, its cooperation has used an aluminum alloy window processing equipment, and this equipment includes that four establish subaerial first backup pad, be equipped with the processing case between the first backup pad, be equipped with aluminum alloy window conveying strutting arrangement on the first backup pad, the processing incasement bottom is equipped with aluminum alloy window crookedness and detects sieving mechanism, processing incasement top bilateral symmetry is equipped with the fixed device of straightening of aluminum alloy window, be equipped with aluminum alloy window cutting device between the fixed device of straightening of aluminum alloy window.

Preferably, aluminum alloy window conveying and supporting device still includes that two symmetries are established at the second backup pad of processing bottom of the case portion, every be equipped with the third backup pad between first backup pad and the processing case, the symmetry is equipped with the conveyer belt between the third backup pad of processing case both sides, be parallel to conveyer belt one side in the processing case and be equipped with the waste link groove, processing incasement aluminum alloy window cutting device below is equipped with the scrap groove.

Preferably, the aluminum alloy window bending degree detecting and screening device comprises a first hydraulic cavity arranged at the upper end of the second supporting plate, a first hydraulic rod is arranged in the first hydraulic cavity, a first spring is arranged between the first hydraulic rod and the first hydraulic cavity, each first hydraulic rod is symmetrically provided with two fourth supporting plates, a rotating shaft is arranged between the fourth supporting plates, each rotating shaft is provided with a roller, and each first hydraulic cavity is provided with a first oil way at the bottom.

Preferably, a second oil path is arranged on one side, close to the discharge end, of the first oil path, a second hydraulic cavity is arranged at the tail end of the second oil path, the second hydraulic cavity is located on the first oil path, close to the feed end, a first slider is arranged in the second hydraulic cavity, a third hydraulic cavity is connected to the tail end of the first oil path, a second slider is arranged in the third hydraulic cavity, second springs are symmetrically arranged on two sides between the second slider and the third hydraulic cavity, two third oil paths are symmetrically arranged on one side, close to the inner side, of the third hydraulic cavity in a left-right mode, a fourth hydraulic cavity is arranged at the other end of each third oil path, a third slider is arranged in each fourth hydraulic cavity, a third spring is connected to one side, far away from the third oil path, of each third slider and the fourth hydraulic cavity, a first switch is arranged on one side, far away from the third oil path, of each fourth hydraulic cavity is coaxially arranged with the third oil path, and a fifth hydraulic cavity is formed in the other side of each fourth oil way, and a second hydraulic rod is arranged in each fifth hydraulic cavity.

Preferably, fifth hydraulic pressure chambers are symmetrically arranged on the left and right of the top of the third hydraulic pressure chamber, a fourth slider is arranged in each fifth hydraulic pressure chamber, a fourth spring is arranged between each fifth hydraulic pressure chamber and each fourth slider, a sixth hydraulic pressure chamber is arranged between each fifth hydraulic pressure chamber, a fifth oil path is arranged between each fifth hydraulic pressure chamber and each sixth hydraulic pressure chamber, a sixth oil path is arranged on each sixth hydraulic pressure chamber and is horizontally vertical to the fifth oil path, and a baffle is arranged on each second slider at the sixth oil path.

Preferably, the aluminum alloy window fixing and straightening device comprises fifth supporting plates arranged at the tops of the processing boxes, a plurality of pressing parts are arranged in each fifth supporting plate, each pressing part comprises a seventh hydraulic cavity arranged on the fifth supporting plate, a third hydraulic rod is arranged in each seventh hydraulic cavity, a sliding groove is arranged in each third hydraulic rod, a sliding rod is arranged in each sliding groove, a fifth spring is arranged between each sliding rod and the sliding groove, a second switch is arranged at the bottom of each sliding groove, the tail end of each sixth oil path is connected with the first seventh hydraulic cavity, and a seventh oil path is arranged between each seventh hydraulic cavity.

Preferably, the aluminum alloy window cutting device comprises a hydraulic tank arranged between a fifth support plate arranged at the top of the processing tank, the sixth oil path is arranged at the top of the hydraulic tank, the hydraulic tank is provided with a sixth support plate, an eighth hydraulic cavity is arranged in the sixth support plate, a fourth hydraulic rod is arranged in the eighth hydraulic cavity, a servo motor is arranged at the bottom of the fourth hydraulic rod, and a blade is arranged at the output end of the servo motor.

Preferably, the processing technology of the aluminum alloy window comprises the following steps:

s1: the aluminum alloy rod is placed on a conveyor belt, the conveyor belt sends the aluminum alloy rod into a processing box, friction is reduced when the aluminum alloy rod passes through rollers, the aluminum alloy rod is different in bending angle, the rollers are pressed downwards to different degrees, the rollers drive a rotating shaft to press downwards, the rotating shaft drives a fourth supporting plate to press downwards, the fourth supporting plate drives a first hydraulic rod to press downwards, so that hydraulic oil enters a first oil way, the hydraulic oil enters a second oil way from the first oil way, the hydraulic oil pushes and opens a first sliding block, when the bending angle of the aluminum alloy rod is too large, a third hydraulic cavity is communicated with a third oil way, the third sliding block touches a first switch to open the fourth oil way, the hydraulic oil enters a fifth hydraulic cavity at one time, and the second hydraulic rod pushes the aluminum alloy rod into a waste rod groove;

s2: when the bending angle of the aluminum alloy rod is smaller, hydraulic oil in the third hydraulic cavity pushes the fourth slider to enter the sixth hydraulic cavity through the fifth oil path, the different bending angles of the aluminum alloy rod drive the baffle to open sixth oil paths with different sizes, the hydraulic oil enters the seventh hydraulic cavity through the sixth oil path to push the third hydraulic rod to move forwards, the third hydraulic rod drives the sliding rod to press the aluminum alloy rod forwards, the pressure is increased until the sliding rod touches the second switch to open the seventh oil path, the hydraulic oil enters the next seventh hydraulic cavity, the larger the bending angle of the aluminum alloy rod is, the more pressing parts are pressed, the smaller bending rods are pressed and straightened better when the aluminum alloy rod is fixed;

s3: the hydraulic tank pushes the fourth hydraulic rod to move in the sixth supporting plate, the fourth hydraulic rod drives the servo motor to move downwards, and the servo motor drives the blade to cut the aluminum alloy rod.

Has the advantages that:

1. the conveyer belt sends into the aluminum alloy pole processing incasement, the aluminum alloy pole reduces the friction when the gyro wheel, aluminum alloy pole bending angle is different, press the gyro wheel down to a different extent, when aluminum alloy pole bending angle is too big, third hydraulic pressure chamber intercommunication third oil circuit, the third slider touches first switch and opens the fourth oil circuit, hydraulic oil once only gets into the fifth hydraulic pressure chamber, the second hydraulic pressure pole pushes this aluminum alloy pole into useless pole inslot, reach the automatic effect of selecting the aluminum alloy pole that is not conform to the requirements.

2. Hydraulic oil in the third hydraulic chamber pushes a fourth slider to enter a sixth hydraulic chamber through a fifth oil path, different bending angles of the aluminum alloy rods drive the baffle to open sixth oil paths with different sizes, the hydraulic oil enters a seventh hydraulic chamber through the sixth oil path to push the third hydraulic rod to move forwards, the third hydraulic rod drives the slide rod to push the aluminum alloy rods forwards, pressure is increased until the slide rod touches the second switch to open the seventh oil path, the hydraulic oil enters the next seventh hydraulic chamber, the larger bending angle of the aluminum alloy rods is, the more pressing quantity of pressing parts is pressed, and the effect of fixing the aluminum alloy rods and better straightening the small bending rods is achieved.

3. And the aluminum alloy window is cut in the 45-degree angle direction, so that secondary processing is not needed, and the production efficiency is improved.

Drawings

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

FIG. 2 is a front cross-sectional view of the present invention;

FIG. 3 is a side cross-sectional view of the present invention;

FIG. 4 is a top cross-sectional view of a tortuosity-detecting screening apparatus of the present invention;

FIG. 5 is a front cross-sectional view of a tortuosity detection screening apparatus of the present invention;

fig. 6 is a partially enlarged view of a portion a in fig. 2.

In the figure: a first support plate 101, a processing box 102, an aluminum alloy window conveying support device 1, a second support plate 104, a third support plate 105, a conveying belt 103, a waste rod groove 106, a waste scrap groove 107, an aluminum alloy window bending degree detection screening device 2, a first hydraulic chamber 201, a first hydraulic rod 202, a first spring 203, a fourth support plate 204, a rotating shaft 205, a roller 206, a first oil path 207, a second oil path 208, a second hydraulic chamber 209, a first slider 210, a third hydraulic chamber 211, a second slider 212, a second spring 213, a third oil path 214, a fourth hydraulic chamber 215, a third slider 216, a third spring 217, a first switch 218, a fourth oil path 219, a fifth hydraulic chamber 220, a second hydraulic rod 221, a fifth hydraulic chamber 222, a fourth slider 223, a fourth spring 224, a sixth hydraulic chamber 226, a fifth oil path 225, a sixth oil path 228, a baffle 227, a window fixing straightening device 3, a fifth support plate 309, the device comprises a pressing component 301, a seventh hydraulic cavity 302, a third hydraulic rod 303, a sliding chute 304, a sliding rod 305, a fifth spring 306, a second switch 307, a seventh oil path 308, the aluminum alloy window cutting device 4, a hydraulic tank 401, a sixth supporting plate 403, an eighth hydraulic cavity 402, a fourth hydraulic rod 404, a servo motor 405 and a blade 406.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that the terms "inside", "below", and the like refer to orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention conventionally place when used, and are used only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

The utility model provides an aluminum alloy window processing technology, it has used an aluminum alloy window processing equipment in cooperation, this equipment includes that four establish subaerial first backup pad 101, be equipped with processing case 102 between the first backup pad 101, be equipped with aluminum alloy window conveying strutting arrangement 1 on the first backup pad 101, the bottom is equipped with aluminum alloy window crookedness and detects sieving mechanism 2 in the processing case 102, top bilateral symmetry is equipped with the fixed device 3 that straightens of aluminum alloy window in the processing case 102, be equipped with aluminum alloy window cutting device 4 between the fixed device 3 that straightens of aluminum alloy window.

Further, with reference to fig. 1, 2 and 3, the aluminum alloy window conveying and supporting device 1 further includes two second supporting plates 104 symmetrically arranged at the bottom of the processing box 102, a third supporting plate 105 is arranged between each first supporting plate 101 and the processing box 102, a conveying belt 103 is symmetrically arranged between the third supporting plates 105 at two sides of the processing box 102, a waste rod groove 106 is arranged in the processing box 102 and parallel to one side of the conveying belt 103, and a waste scrap groove 107 is arranged below the aluminum alloy window cutting device 4 in the processing box 102.

Further, with reference to fig. 2, 3, 4, and 5, the aluminum alloy window curvature detecting and screening device 2 includes a first hydraulic chamber 201 established at the upper end of each second support plate 104, a first hydraulic rod 202 is arranged in each first hydraulic chamber 201, a first spring 203 is arranged between each first hydraulic rod 202 and the first hydraulic chamber 201, two fourth support plates 204 are symmetrically arranged on the parallel conveyor belt 103 at the upper end of each first hydraulic rod 202, a rotation shaft 205 is arranged between each fourth support plate 204, a roller 206 is arranged on each rotation shaft 205, and a first oil path 207 is arranged at the bottom of each first hydraulic chamber 201.

Further, with reference to fig. 2, 3, 4 and 5, a second oil path 208 is provided on one side of the first oil path 207 near the discharge end, a second hydraulic cavity 209 is provided at the end of the second oil path 208, the second hydraulic cavity 209 is located on the first oil path 207 near the feed end, a first slider 210 is provided in the second hydraulic cavity 209, a third hydraulic cavity 211 is provided at the end of the first oil path 207 in a connecting manner, a second slider 212 is provided in the third hydraulic cavity 211, second springs 213 are symmetrically provided on both sides between the second slider 212 and the third hydraulic cavity 211, two third oil paths 214 are symmetrically provided on one side of the third hydraulic cavity 211 near the inner side, a fourth hydraulic cavity 215 is provided at the other end of each third oil path 214, a third slider 216 is provided in each fourth hydraulic cavity 215, a third spring 217 is connected to one side of each third slider 216 and the fourth hydraulic cavity 215 far from the third oil path 214, a first switch 218 is provided on one side of each fourth hydraulic cavity 215 far from the third oil path 214, a fourth oil path 219 is coaxially provided with the third oil path 214 on the inward side of each fourth hydraulic chamber 215, a fifth hydraulic chamber 220 is provided on the other side of each fourth oil path 219, and a second hydraulic rod 221 is provided in each fifth hydraulic chamber 220.

Further, with reference to fig. 2, 3, 4, and 5, fifth hydraulic chambers 222 are symmetrically disposed on the top of the third hydraulic chamber 211 left and right, a fourth slider 223 is disposed in each fifth hydraulic chamber 222, a fourth spring 224 is disposed between each fifth hydraulic chamber 222 and the fourth slider 223, a sixth hydraulic chamber 226 is disposed between the fifth hydraulic chambers 222, a fifth oil path 225 is disposed between each fifth hydraulic chamber 222 and the sixth hydraulic chamber 226, a sixth oil path 228 is disposed on the sixth hydraulic chamber 226 and horizontally and vertically to the fifth oil path 225, and a baffle 227 is disposed on the sixth oil path 228 on the second slider 212.

Further, with reference to fig. 1, 2 and 6, the aluminum alloy window fixing and straightening device 3 includes fifth support plates 309 disposed at the top of the processing box 102, each fifth support plate 309 is provided with a plurality of pressing members 301, each pressing member 301 includes seventh hydraulic cavities 302 disposed on the fifth support plates 309, each seventh hydraulic cavity 302 is provided with a third hydraulic rod 303, each third hydraulic rod 303 is provided with a sliding chute 304, each sliding chute 304 is provided with a sliding rod 305, a fifth spring 306 is disposed between each sliding rod 305 and the sliding chute 304, the bottom of each sliding chute 304 is provided with a second switch 307, the end of each sixth oil path 228 is connected with the first seventh hydraulic cavity 302, and a seventh oil path 308 is disposed between each seventh hydraulic cavity 302.

Further, with reference to fig. 1 and 2, the aluminum alloy window cutting device 4 includes a hydraulic tank 401 disposed between fifth support plates 309 disposed on the top of the processing tank 102, a sixth oil path 228 disposed on the top of the hydraulic tank 401, the hydraulic tank 401 having a sixth support plate 403, an eighth hydraulic chamber 402 disposed in the sixth support plate 403, a fourth hydraulic rod 404 disposed in the eighth hydraulic chamber 402, a servo motor 405 disposed at the bottom of the fourth hydraulic rod 404, and a blade 406 disposed at an output end of the servo motor 405.

Further, with reference to fig. 1, 2, 3, 4, 5 and 6, the processing technology of the aluminum alloy window comprises the following steps:

s1: placing aluminum alloy rods on a conveyor belt 103, conveying the aluminum alloy rods into a processing box 102 by the conveyor belt 103, reducing friction when the aluminum alloy rods pass through rollers 206, enabling the aluminum alloy rods to have different bending angles, pressing the rollers 206 downwards to different degrees, driving a rotating shaft 205 to press downwards by the rollers 206, driving a fourth supporting plate 204 to press downwards by the rotating shaft 205, driving a first hydraulic rod 202 to press downwards by the fourth supporting plate 204, enabling hydraulic oil to enter a first oil path 207, enabling the hydraulic oil to enter a second oil path 208 from the first oil path 207, pushing and opening a first sliding block 210 by the hydraulic oil, when the bending angle of the aluminum alloy rods is too large, enabling a third hydraulic cavity 211 to be communicated with a third oil path 214, enabling a third sliding block 216 to touch a first switch 218 to open a fourth oil path 219, enabling the hydraulic oil to enter a fifth hydraulic cavity 220 at one time, and pushing the aluminum alloy rods into a waste rod groove 106 by a second hydraulic rod 221;

s2: when the bending angle of the aluminum alloy rod is smaller, hydraulic oil in the third hydraulic cavity 211 pushes the fourth slider 223 away to enter the sixth hydraulic cavity 226 through the fifth oil path 225, the different bending angles of the aluminum alloy rod drive the baffle 227 to open the sixth oil paths 228 with different sizes, the hydraulic oil enters the seventh hydraulic cavity 302 through the sixth oil paths 228 to push the third hydraulic rod 303 to move forward, the third hydraulic rod 303 drives the sliding rod 305 to press the aluminum alloy rod forward, the pressure is increased until the sliding rod 305 touches the second switch 307 to open the seventh oil path 308, the hydraulic oil enters the next seventh hydraulic cavity 302, and the larger the bending angle of the aluminum alloy rod, the larger the pressing number of the pressing part 301 is, and the smaller bending rod is pressed better while the aluminum alloy rod is fixed;

s3: the hydraulic tank 401 pushes the fourth hydraulic rod 404 to move in the sixth supporting plate 403, the fourth hydraulic rod 404 drives the servo motor 405 to move downwards, and the servo motor 405 drives the blade 406 to cut the aluminum alloy rod.

The working principle is as follows: aluminum alloy rods are placed on the conveyor belt 103, the conveyor belt 103 sends the aluminum alloy rods into the processing box 102, friction is reduced when the aluminum alloy rods pass through the roller 206, the bending angles of the aluminum alloy rods are different, the roller 206 is pressed downwards to different degrees, the roller 206 drives the rotating shaft 205 to press downwards, the rotating shaft 205 drives the fourth supporting plate 204 to press downwards, the fourth supporting plate 204 drives the first hydraulic rod 202 to press downwards, hydraulic oil enters the first oil way 207, the hydraulic oil enters the second oil way 208 from the first oil way 207, the first sliding block 210 is opened by pushing of the hydraulic oil, when the bending angle of the aluminum alloy rods is too large, the third hydraulic cavity 211 is communicated with the third oil way 214, the third sliding block 216 touches the first switch 218 to open the fourth oil way 219, the hydraulic oil enters the fifth hydraulic cavity 220 at one time, and the second hydraulic rod 221 pushes the aluminum alloy rods into the waste rod groove 106.

When the bending angle of the aluminum alloy rod is smaller, hydraulic oil in the third hydraulic cavity 211 pushes the fourth slider 223 away to enter the sixth hydraulic cavity 226 through the fifth oil path 225, the different bending angles of the aluminum alloy rod drive the baffle 227 to open the sixth oil path 228 with different sizes, the hydraulic oil enters the seventh hydraulic cavity 302 through the sixth oil path 228 to push the third hydraulic rod 303 to move forward, the third hydraulic rod 303 drives the sliding rod 305 to press the aluminum alloy rod forward, the pressure is increased until the sliding rod 305 touches the second switch 307 to open the seventh oil path 308, the hydraulic oil enters the next seventh hydraulic cavity 302, and the larger the bending angle of the aluminum alloy rod, the larger the pressing number of the pressing part 301 is, and the smaller bending rod is pressed better while the aluminum alloy rod is fixed. The hydraulic tank 401 pushes the fourth hydraulic rod 404 to move in the sixth supporting plate 403, the fourth hydraulic rod 404 drives the servo motor 405 to move downwards, and the servo motor 405 drives the blade 406 to cut the aluminum alloy rod.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.