CN116460644A - Cutting device for processing aluminum alloy door and window frame - Google Patents

Abstract

The invention discloses a cutting device for processing an aluminum alloy door and window frame, and belongs to the field of cutting devices. Cutting device is used in processing of aluminum alloy door and window frame, including the cutting bench, still include: the two support posts are fixedly connected to the cutting table, a transverse sliding rod is fixedly connected between the two support posts, a sliding table is slidably arranged on the transverse sliding rod, telescopic equipment is fixedly arranged on one support post, and the telescopic end of the telescopic equipment is fixedly connected with the sliding table; the cutting device comprises a shell with a downward opening, and a sliding table fixedly connected with the shell, wherein a cutting wheel is rotatably arranged in the shell through a rotating shaft, and a driving motor for driving the rotating shaft to rotate is fixedly arranged on the sliding table; the invention can enable burrs generated by cutting to incline to the middle part of the tubular aluminum alloy section, and simultaneously, partial burrs can be polished by the cutting wheel, thereby effectively improving the quality of the aluminum alloy section and indirectly improving the aesthetic property of the aluminum alloy door and window frame.

Description

Cutting device for processing aluminum alloy door and window frame

Technical Field

The invention relates to the technical field of cutting devices, in particular to a cutting device for processing an aluminum alloy door and window frame.

Background

The aluminum alloy door and window frame is widely applied to the fields of building doors and windows, curtain walls, suspended ceilings and the like. The novel building decoration board can meet the requirements of different building styles and different design requirements, and has good durability and attractive appearance. Meanwhile, the aluminum alloy door and window frame can save energy and reduce carbon emission, and accords with the modern environment-friendly concept.

In the processing of aluminum alloy door and window frames, it is often necessary to cut strip aluminum alloy raw material to a desired length using cutting equipment. However, since the cutting wheel cuts the aluminum alloy raw material in only one direction during the cutting process, burrs directed to one side are easily generated on the cut section, and the burrs easily affect the aesthetic appearance of the aluminum alloy door and window frame. In addition, the cutting wheel can generate larger noise during cutting, and the main reason is that severe friction can be generated between the disc body and the cutting groove wall, and particularly when the cutting depth is larger, the noise can be more obvious.

Disclosure of Invention

The invention aims to solve the problem that in the prior art, obvious burrs and noise are easy to generate when an aluminum alloy door and window frame material is cut, and provides a cutting device for processing an aluminum alloy door and window frame.

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

cutting device is used in processing of aluminum alloy door and window frame, including the cutting bench, still include: the two support posts are fixedly connected to the cutting table, a transverse sliding rod is fixedly connected between the two support posts, a sliding table is slidably arranged on the transverse sliding rod, telescopic equipment is fixedly arranged on one support post, and the telescopic end of the telescopic equipment is fixedly connected with the sliding table; the cutting device comprises a shell with a downward opening, and a sliding table fixedly connected with the shell, wherein a cutting wheel is rotatably arranged in the shell through a rotating shaft, and a driving motor for driving the rotating shaft to rotate is fixedly arranged on the sliding table; two front and back symmetrical support plates are fixedly installed on the cutting table, wherein two support plates are rotatably connected with sleeves, two sleeves are fixedly provided with clamps, and a rotation mechanism for driving the two sleeves to rotate is arranged on the transverse sliding rod.

For driving the sleeve pipe to rotate, preferably, rotation mechanism is including rotating the first transmission shaft of connecting between two the extension board, two equal fixed mounting has first gear on the sheathed tube outer wall, wherein, the both ends of first transmission shaft are equal fixed mounting and first gear engagement's second gear, the lower extreme of horizontal slide bar has the slide through first spout sliding connection, through first spring elastic connection between slide and the slip table, be equipped with in the first spout with slide complex kayser subassembly, be connected through drive assembly between slide and one of them sleeve pipe.

In order to prevent the cutting wheel from driving the sleeve to rotate, further, the transmission assembly comprises a second transmission shaft which is rotatably arranged on one of the support plates, the second transmission shaft is connected with the sleeve through a worm gear and a worm, a third transmission shaft is rotatably connected to the support column, the lower end of the third transmission shaft is connected with the second transmission shaft through two meshed bevel gears, a driven gear is fixedly arranged at the upper end of the third transmission shaft, and a rack meshed with the driven gear is fixedly arranged on the sliding plate.

In order to enable the rack to automatically slide, further, the clamping and locking assembly comprises a second sliding groove arranged at the upper end of the sliding plate, a wedge block is connected in the second sliding groove in a sliding mode, the wedge block is elastically connected with the inner bottom of the second sliding groove through a second spring, a clamping groove matched with the wedge block is formed in the first sliding groove, a trigger block matched with the clamping groove is fixedly connected onto the sliding table, permanent magnets are fixedly arranged in the trigger block and the wedge block, opposite magnetic poles of the two permanent magnets are identical, the clamping groove is located at the upper ends of the two sleeves, and a hydraulic buffer is fixedly arranged between the sliding plate and the inner wall of the first sliding groove.

In order to dissipate heat of the cutting wheel, preferably, a radiating pipe communicated with the radiating pipe is arranged on the upper end side wall of the housing, a telescopic mechanism is arranged on the side wall of the housing and connected with a vertical plate, a driving shaft extending into the radiating pipe is rotatably connected to the upper end side wall of the vertical plate, radiating fan blades are fixedly mounted on the driving shaft, a fourth driving shaft coaxial with the rotating shaft is rotatably connected to the lower end side wall of the vertical plate, the fourth driving shaft is connected with the driving shaft through chain transmission, a first friction plate facing the fourth driving shaft is fixedly mounted at one end of the rotating shaft, and a second friction plate matched with the first friction plate is fixedly mounted on the fourth driving shaft.

In order to enable the first friction disc to be automatically engaged with the second friction disc, the telescopic mechanism further comprises a guide rod fixedly installed on the outer wall of the housing, the vertical plate is connected to the guide rod in a sliding mode, the vertical plate is elastically connected with the outer wall of the housing through a third spring, one of the supporting columns is fixedly connected with a push rod matched with the vertical plate, and when the housing moves to the upper end of the sleeve, the push rod pushes the vertical plate upwards in a direction away from the housing.

In order to prevent the cutting wheel from being subjected to resistance of the driving motor, further, a first polygonal rod is fixedly connected to an output shaft of the driving motor, a sliding tube is slidably connected to the outer wall of the first polygonal rod, third friction discs are fixedly mounted at the opposite ends of the sliding tube and the rotating shaft, gear teeth are arranged on the opposite faces of the two third friction discs, a pushing plate is fixedly connected to the outer wall of the sliding tube, and the pushing plate is fixedly connected with a vertical plate through a connecting rod.

In order to keep the cutting wheel clean, further, the inner wall of the housing is fixedly provided with a blowing nozzle, the air outlet of the blowing nozzle faces the edge of the cutting wheel, the air outlet of the blowing nozzle faces the radiating pipe, and the second friction plate is provided with an air supply assembly for supplying air to the blowing nozzle.

In order to automatically supply air to the blowing nozzle, further, the air supply assembly comprises a plurality of third sliding grooves arranged on the second friction disc, a plurality of sliding blocks are connected in the third sliding grooves in a sliding manner, the sliding blocks are elastically connected with the inner walls of the third sliding grooves through fourth springs, cambered surface convex blocks matched with the sliding blocks are fixedly arranged on the first friction disc, an air suction pipe and an air exhaust pipe which are communicated with the third sliding grooves are arranged on the second friction disc, and an air transmission pipe communicated with the air exhaust pipe is fixedly arranged in the fourth transmission shaft and is communicated with the blowing nozzle through a connecting pipe.

In order to prevent dust and peculiar smell from directly drifting into the air, further, a filter element is detachably arranged in the radiating tube.

Compared with the prior art, the invention provides the cutting device for processing the aluminum alloy door and window frame, which has the following beneficial effects:

1. according to the cutting device for processing the aluminum alloy door and window frame, the inner aluminum alloy section bar can be driven to slowly rotate through the two rotating sleeves, burrs generated by cutting can be inclined to the middle part of the tubular aluminum alloy section bar by winding cutting, and meanwhile, part of burrs can be polished by the cutting wheel, so that the quality of the aluminum alloy section bar can be effectively improved, and the attractiveness of the aluminum alloy door and window frame is indirectly improved;

2. according to the cutting device for processing the aluminum alloy door and window frame, the driving shaft is driven to rotate by the inertia force generated when the cutting wheel is stopped, the driving shaft can drive the radiating fan blades to rotate in the radiating pipe, the airflow flowing in the housing can effectively radiate the cutting wheel, so that the cutting wheel can radiate in time, and peculiar smell and dust generated during cutting can be absorbed;

3. according to the cutting device for processing the aluminum alloy door and window frame, the third friction disc is driven to be far away from the third friction disc on the rotating shaft through the push plate, at this time, the cutting wheel which rotates by inertia does not drive the sliding tube to rotate, so that the first polygonal rod is not driven to rotate, and the output shaft of the driving motor is not driven to rotate, the cutting wheel is not subjected to the resistance of the driving motor, and the power of the cutting wheel for driving the cooling fan blades is more sufficient;

4. this cutting device is used in processing of aluminum alloy door and window frame is slipped on the lateral wall of first friction disc through pivoted second friction disc to drive a plurality of sliders and sweep a plurality of cambered surface lugs in proper order, the blowing mouth then can intermittent type nature blow to the edge of cutting wheel, thereby can blow off the iron cutting that glues on the cutting wheel teeth, makes the cutting wheel keep clean, promotes the cutting efficiency of cutting wheel indirectly, and can carry out high-efficient heat dissipation to the cutting wheel.

Drawings

Fig. 1 is a schematic view of a first view angle axis measurement structure of a cutting device for processing an aluminum alloy door and window frame according to the present invention;

fig. 2 is a schematic view of a second view angle axis measurement structure of a cutting device for processing an aluminum alloy door and window frame according to the present invention;

fig. 3 is a schematic view of a partial axial measurement structure of a cutting device for processing an aluminum alloy door and window frame according to the present invention;

FIG. 4 is a schematic diagram showing a cut-away structure of a housing of a cutting device for processing an aluminum alloy door and window frame according to the present invention;

FIG. 5 is a schematic view showing a cross slide bar cut-away structure of a cutting device for processing an aluminum alloy door and window frame according to the present invention;

FIG. 6 is an enlarged view of portion A of FIG. 5 showing a cutting device for processing an aluminum alloy door and window frame according to the present invention;

FIG. 7 is a schematic view of a part of the cutting device for processing an aluminum alloy door and window frame in FIG. 4;

fig. 8 is a schematic diagram of a part of the cutting device for processing an aluminum alloy door and window frame according to the second embodiment of the present invention in fig. 4.

In the figure: 1. a cutting table; 2. a support post; 3. a transverse slide bar; 4. a sliding table; 5. a telescoping device; 6. a housing; 7. a rotating shaft; 8. a cutting wheel; 9. a driving motor; 10. a support plate; 11. a sleeve; 12. a clamp; 13. a first drive shaft; 14. a first gear; 15. a second gear; 16. a second drive shaft; 17. a worm gear; 18. a third drive shaft; 19. bevel gears; 20. a rack; 21. a driven gear; 22. a first chute; 23. a slide plate; 24. a first spring; 25. a second chute; 26. wedge blocks; 27. a clamping groove; 28. a second spring; 29. a trigger block; 30. a hydraulic buffer; 31. a heat radiating pipe; 32. a riser; 33. a guide rod; 34. an air exchanging pipe; 35. a third spring; 36. a first friction plate; 37. a second friction plate; 38. a fourth drive shaft; 39. a drive shaft; 40. chain transmission; 41. radiating fan blades; 42. a third chute; 43. a slide block; 44. a fourth spring; 45. a cambered surface convex block; 46. an exhaust pipe; 47. an air suction pipe; 48. a gas pipe; 49. a connecting pipe; 49. a connecting rod; 50. an air blowing nozzle; 51. a push rod; 52. a push plate; 53. a first polygonal bar; 54. a slide tube; 55. a third friction plate; 56. a filter element; 57. a rotating rod; 58. a collar; 59. a cleaning rod; 60. a brush; 61. a limiting plate; 62. a telescopic air bag; 63. a connecting rod; 64. a second polygonal bar; 65. and a slide hole.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

In the description of the present invention, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present invention and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Example 1:

referring to fig. 1 to 8, a cutting device for processing an aluminum alloy door and window frame comprises a cutting table 1, and further comprises: the two support posts 2 are fixedly connected to the cutting table 1, wherein a transverse sliding rod 3 is fixedly connected between the two support posts 2, a sliding table 4 is slidably arranged on the transverse sliding rod 3, a telescopic device 5 is fixedly arranged on one support post 2, the telescopic device 5 is an electric telescopic rod, and a telescopic end of the telescopic device 5 is fixedly connected with the sliding table 4; the casing 6 with a downward opening is fixedly connected to the sliding table 4, wherein a cutting wheel 8 is rotatably arranged in the casing 6 through a rotating shaft 7, and a driving motor 9 for driving the rotating shaft 7 to rotate is fixedly arranged on the sliding table 4; two support plates 10 which are symmetrical from front to back are fixedly arranged on the cutting table 1, wherein the two support plates 10 are respectively and rotatably connected with a sleeve 11, clamps 12 are respectively and fixedly arranged on the two sleeves 11, the clamps 12 are used for fixing workpieces into the sleeves 11, and a rotation mechanism for driving the two sleeves 11 to rotate is arranged on the transverse slide bar 3.

When in use, the tubular aluminum alloy section to be cut is inserted into the two sleeves 11, the tubular aluminum alloy section can be round in section and square in section, then the tubular aluminum alloy section is fixed onto the two sleeves 11 through the clamps 12, then the sliding table 4 is driven to move towards the upper ends of the two clamps 12 through the telescopic equipment 5, the housing 6 and the cutting wheel 8 can be driven to synchronously move, the driving motor 9 is turned on, the driving motor 9 can drive the cutting wheel 8 to rotate to complete cutting action, when the cutting wheel 8 moves to the position right above the two clamps 12, the telescopic equipment 5 stops moving, the cutting wheel 8 can cut the upper end of the tubular aluminum alloy section and cut through the upper end of the aluminum alloy section, at the moment, the rotating mechanism can drive the two sleeves 11 to rotate, the two sleeves 11 can drive the internal aluminum alloy section to slowly rotate through the clamps 12, at the moment, the cutting wheel 8 can cut around the outer wall of the aluminum alloy section, the cutting work of the aluminum alloy section can be completed, in the cutting process, the cutting depth of the cutting wheel 8 is low, the friction can be effectively reduced, the noise is generated, the friction is reduced, the friction is greatly improved, the upper end of the tubular aluminum alloy section can also can be cut through the sliding table, the sliding window 8 can also be cut into the shape, the middle part can be cut, the sliding window section can be cut, the cut edge can be cut into the window section can be cut, and the window section has attractive quality, and the cut can be cut, and has attractive quality, and has the attractive quality, and can be cut.

Example 2:

referring to fig. 1-3 and 5, substantially the same as in example 1, further, a specific embodiment of the rotation mechanism is specifically disclosed.

The rotation mechanism comprises a first transmission shaft 13 which is rotationally connected between two support plates 10, first gears 14 are fixedly arranged on the outer walls of two sleeves 11, second gears 15 meshed with the first gears 14 are fixedly arranged at two ends of the first transmission shaft 13, a sliding plate 23 is slidably connected to the lower end of a transverse sliding rod 3 through a first sliding groove 22, the sliding plate 23 is elastically connected with a sliding table 4 through a first spring 24, a locking assembly matched with the sliding plate 23 is arranged in the first sliding groove 22, and the sliding plate 23 is connected with one sleeve 11 through a transmission assembly.

During the moving period of the sliding table 4, the sliding table 4 can compress the first spring 24, the sliding plate 23 can be subjected to the jacking force of the first spring 24, when the sliding table 4 drives the cutting wheel 8 to move the cutting station, the locking assembly does not limit the sliding plate 23 any more, the sliding plate 23 can slide in the direction away from the first spring 24 under the jacking force of the first spring 24, the sliding plate 23 can drive the two sleeves 11 to synchronously rotate through the transmission assembly, and therefore the tubular aluminum alloy section is driven to rotate circumferentially, and rotary winding cutting is completed.

The transmission assembly comprises a second transmission shaft 16 rotatably arranged on one support plate 10, the second transmission shaft 16 is connected with the sleeve 11 through a worm gear 17, a third transmission shaft 18 is rotatably connected to the support post 2, the lower end of the third transmission shaft 18 is connected with the second transmission shaft 16 through two meshed bevel gears 19, a driven gear 21 is fixedly arranged at the upper end of the third transmission shaft 18, and a rack 20 meshed with the driven gear 21 is fixedly arranged on a sliding plate 23;

when the sliding plate 23 slides towards the direction far away from the first spring 24, the sliding plate 23 drives the rack 20 to synchronously slide, the rack 20 drives the third transmission shaft 18 to rotate through the driven gear 21, the third transmission shaft 18 drives the second transmission shaft 16 to rotate through the two meshed bevel gears 19, the second transmission shaft 16 drives one of the sleeves 11 to rotate through the worm gear 17, one of the sleeves 11 drives the second gear 15 to rotate through the first gear 14, the second gear 15 drives the other second gear 15 to rotate through the first transmission shaft 13, the other sleeve 11 is driven to rotate, the two rotating sleeves 11 drive the inner aluminum alloy section to slowly rotate, and at the moment, the cutting wheel 8 cuts around the outer wall of the aluminum alloy section.

Example 3:

referring to fig. 5 and 6, substantially the same as example 2, further, a particular embodiment of a latch assembly is specifically disclosed.

The locking assembly comprises a second chute 25 arranged at the upper end of the sliding plate 23, a wedge block 26 is slidably connected in the second chute 25, the wedge block 26 is elastically connected with the inner bottom of the second chute 25 through a second spring 28, a clamping groove 27 matched with the wedge block 26 is arranged in the first chute 22, a trigger block 29 matched with the clamping groove 27 is fixedly connected to the sliding table 4, permanent magnets are fixedly arranged in the trigger block 29 and the wedge block 26, opposite magnetic poles of the two permanent magnets are the same, the clamping groove 27 is positioned at the upper ends of the two sleeves 11, and a hydraulic buffer 30 is fixedly arranged between the sliding plate 23 and the inner wall of the first chute 22;

when the sliding table 4 drives the cutting wheel 8 to move the cutting station, the sliding table 4 can drive the trigger block 29 to move to the position right above the wedge block 26, the trigger block 29 and the permanent magnet in the wedge block 26 generate repulsive force, then the wedge block 26 is completely pushed into the second sliding groove 25 by repulsive force, the sliding plate 23 is not limited by the wedge block 26 any more, the sliding plate 23 can drive the rack 20 to slide in the direction far away from the first spring 24 under the pushing action of the first spring 24, when the cutting is completed, the sliding plate 4 and the cutting wheel 8 are driven to reversely slide and reset through the telescopic device 5, the sliding plate 23 can be pulled to the initial position by the first spring 24, when the wedge block 26 is aligned with the clamping groove 27 again, the second spring 28 can drive the wedge block 26 to automatically clamp into the clamping groove 27, when the sliding plate 23 drives the sliding to the rack 20, the sliding of the rack 20 is enabled to be more stable instead of suddenly driving the rack 20 to slide, the sleeve 11 and the aluminum alloy profile inside the sleeve can rotate more stably, the cut can be enabled to be flatter, the quality of the worm gear wheel frame of the aluminum alloy door window is indirectly improved, and the worm wheel 17 can be prevented from rotating automatically when the aluminum alloy window frame is cut, and the worm wheel 8 is prevented from rotating automatically, and the aluminum alloy window frame is cut, and the aluminum window frame is prevented from rotating automatically, and the aluminum alloy window frame is cut from being automatically stable.

Example 4:

referring to fig. 1, 2, 4 and 7, substantially the same as in example 3, a specific embodiment of heat dissipation of the cutting wheel 8 is further added.

The upper end side wall of the housing 6 is provided with a radiating pipe 31 communicated with the radiating pipe, the side wall of the housing 6 is provided with a telescopic mechanism connected with a vertical plate 32, wherein the upper end side wall of the vertical plate 32 is rotationally connected with a driving shaft 39 extending into the radiating pipe 31, a radiating fan blade 41 is fixedly installed on the driving shaft 39, the lower end side wall of the vertical plate 32 is rotationally connected with a fourth transmission shaft 38 coaxial with the rotating shaft 7, the fourth transmission shaft 38 is connected with the driving shaft 39 through a chain transmission 40, one end of the rotating shaft 7 is fixedly provided with a first friction disc 36 facing the fourth transmission shaft 38, the fourth transmission shaft 38 is fixedly provided with a second friction disc 37 matched with the first friction disc 36, the telescopic mechanism comprises a guide rod 33 fixedly installed on the outer wall of the housing 6, the vertical plate 32 is connected onto the guide rod 33 in a sliding mode, the vertical plate 32 is elastically connected with the outer wall of the housing 6 through a third spring 35, a push rod 51 matched with the vertical plate 32 is fixedly connected onto one of the support columns 2, and when the housing 6 moves to the upper end of the sleeve 11, the housing 6 is lifted away from the direction of the housing 6, and a filter element 56 is detachably installed in the housing 31.

When cutting is finished, the driving motor 9 is turned off, and the cutting wheel 8 continuously rotates for a period of time under the action of inertia force; when the housing 6 moves to the upper ends of the two sleeves 11, the ejector rod 51 is inserted into a gap between the vertical plate 32 and the housing 6, the vertical plate 32 is pushed by the ejector rod 51 to be far away from the housing 6, the vertical plate 32 drives the second friction plate 37 to be far away from the first friction plate 36 through the fourth transmission shaft 38, when the rotating shaft 7 drives the cutting blade 8 to rotate, the second friction plate 37 cannot rotate, after cutting is finished, namely, when the housing 6 is reversely slid and reset, the ejector rod 51 cannot push the vertical plate 32, the third spring 35 drives the vertical plate 32 to slide and reset in the direction, the vertical plate 32 drives the second friction plate 37 to push against the first friction plate 36, at this time, because the cutting wheel 8 which rotates by inertia drives the second friction plate 37 to rotate through the first friction plate 36, the second friction plate 37 drives the driving shaft 39 to rotate through the chain transmission 40, the driving shaft 39 drives the cooling blade 41 to rotate in the cooling blade 31, the cooling blade 31 is exhausted outwards, the housing 6 can absorb air through the lower port, the flowing air flow wheel 8 can effectively slide and reset in the direction, and the dust can be conveniently cut and the dust can be filtered, and the dust can be removed, and the dust can be timely removed, and the dust can be filtered, and the dust can be removed.

The output shaft of the driving motor 9 is fixedly connected with a first polygonal rod 53, the outer wall of the first polygonal rod 53 is slidably connected with a slide tube 54, the opposite ends of the slide tube 54 and the rotating shaft 7 are fixedly provided with third friction discs 55, the opposite surfaces of the two third friction discs 55 are provided with gear teeth, the outer wall of the slide tube 54 is fixedly connected with a push plate 52, and the push plate 52 is fixedly connected with the vertical plate 32 through a connecting rod 63;

when the vertical plate 32 drives the second friction disc 37 to approach the first friction disc 36, the vertical plate 32 drives the push plate 52 to synchronously move through the connecting rod 63, the push plate 52 drives the third friction disc 55 to be far away from the third friction disc 55 on the rotating shaft 7 through the slide tube 54, at this time, the cutting wheel 8 which rotates by inertia does not drive the slide tube 54 to rotate, so that the first polygonal rod 53 is not driven to rotate, and then the output shaft of the driving motor 9 is not driven to rotate, so that the cutting wheel 8 is not subjected to the resistance of the driving motor 9, the power of the cutting wheel 8 for driving the heat dissipation fan blades 41 is more sufficient, and during the cutting of the cutting wheel 8, the driving motor 9 drives the slide tube 54 to rotate through the first polygonal rod 53, and the slide tube 54 drives the rotating shaft 7 to rotate through the two abutted third friction discs 55, so that the cutting wheel 8 is driven to rotate;

in order to prevent the generation of intense friction between the two third friction plates 55, the speed of the driving motor 9 is set to be locally raised instead of suddenly rotating at a high speed, so that the gear teeth on the two third friction plates 55 can be slowly meshed together, and the gear teeth can raise the friction force between the two third friction plates 55.

Example 5:

referring to fig. 4 and 8, substantially the same as in example 4, further, a specific embodiment of blowing off the scrap iron on the cutter wheel 8 is specifically added.

The inner wall of the housing 6 is fixedly provided with a blowing nozzle 50, the air outlet of the blowing nozzle 50 faces the edge of the cutting wheel 8, the air outlet of the blowing nozzle 50 also faces the radiating pipe 31, and the second friction disk 37 is provided with an air supply assembly for supplying air to the blowing nozzle 50; the air supply assembly comprises a plurality of third sliding grooves 42 arranged on a second friction disk 37, sliding blocks 43 are slidably connected in the third sliding grooves 42, the sliding blocks 43 are elastically connected with the inner walls of the third sliding grooves 42 through fourth springs 44, cambered surface convex blocks 45 matched with the sliding blocks 43 are fixedly arranged on the first friction disk 36, an air suction pipe 47 and an air discharge pipe 46 which are communicated with the third sliding grooves 42 are arranged on the second friction disk 37, an air delivery pipe 48 communicated with the air discharge pipe 46 is fixedly arranged in a fourth transmission shaft 38, and the air delivery pipe 48 is communicated with an air blowing nozzle 50 through a connecting pipe 49;

in the rotation of second friction disc 37, second friction disc 37 can drive a plurality of sliders 43 circumference to sweep, because resistance when first friction disc 37 and second friction disc 36 just contact is great, then second friction disc 37 can skid on the lateral wall of first friction disc 36, thereby drive a plurality of sliders 43 and sweep a plurality of cambered surface lugs 45 in proper order, when slider 43 aligns with cambered surface lug 45, cambered surface lug 45 can push slider 43 to spout third spout 42 in, the air in the third spout 42 then can receive slider 43's compression, then third spout 42 can discharge the air through blast pipe 46, blast pipe 46 can be through blast pipe 48 and connecting pipe 49 to blowing nozzle 50 air feed, blowing nozzle 50 then can intermittent type nature be to the edge of cutting wheel 8, thereby can keep the cutting efficiency who glues on the tooth of cutting wheel 8, and can indirectly promote cutting wheel 8, when slider 43 is not aligned with cambered surface lug 45, fourth spring 44 can drive slider 43 under the elastic force and slide in the third spout 42, can be in the negative pressure slip in the second spout 37 is in order to the second friction disc 37 is produced, the phenomenon can not slip in the second friction disc 37 is in the second friction disc is had, when the second friction disc 37 is lost, and the second friction disc is not slip can appear.

Example 6:

referring to fig. 4 and 7, substantially the same as in example 5, further, an embodiment of cleaning the outer wall of the cutter wheel 8 is specifically performed.

The inner top of the housing 6 is rotationally connected with a rotating rod 57, one end of the rotating rod 57 is provided with a sliding hole 65, the driving shaft 39 is fixedly connected with a second polygonal rod 64 sliding in the sliding hole 65, the outer walls of the two ends of the rotating rod 57 are respectively and slidingly connected with lantern rings 58, the outer walls of the two lantern rings 58 are respectively and fixedly connected with cleaning rods 59, the two groups of cleaning rods 59 are respectively provided with brushes 60 facing the outer wall of the cutting wheel 8, the two cleaning rods 59 are respectively positioned on the two sides of the cutting wheel 8, the two ends of the rotating rod 57 are respectively and fixedly connected with limiting plates 61, the two limiting plates 61 are respectively and elastically connected with the two lantern rings 58 through telescopic air bags 62, and the sliding hole 65 is communicated with the telescopic air bags 62 through the air exchanging pipes 34;

when the vertical plate 32 approaches the housing 6, the vertical plate 32 drives the second polygonal rod 64 to slide into the sliding hole 65 through the driving shaft 39, gas in the sliding hole 65 is conveyed into the two telescopic air bags 62 through the ventilation pipe 34 under the action of pressure, the two telescopic air bags 62 expand and extend to push the two lantern rings 58 to approach each other, the two lantern rings 58 drive the two groups of brushes 60 to approach each other through the cleaning rod 59, the two groups of brushes 60 abut against the outer wall of the cutting wheel 8, the rotating driving shaft 39 drives the rotating rod 57 to rotate through the second polygonal rod 64, the rotating rod 57 drives the lantern rings 58 to rotate, the cleaning rod 59 cleans the outer wall of the cutting wheel 8 through the brushes 60, but does not clean the gear teeth of the cutting wheel 8, so that when the vertical plate 32 drives the driving shaft 39 and the second polygonal rod 64 to be far away from the rotating rod 57, negative pressure is generated in the sliding hole 65, the gas in the telescopic air bags 62 is sucked, the telescopic air bags 62 can be contracted, the two lantern rings 58 and the brushes 60 are driven to be mutually far away from the cutting wheel 60, and the abrasion of the cutting wheel 8 is prevented.

When the cutting device for processing the aluminum alloy door and window frame is used, a tubular aluminum alloy section to be cut is inserted into two sleeves 11, the tubular aluminum alloy section can be round or square in section, then the tubular aluminum alloy section is fixed on the two sleeves 11 through clamps 12, then the telescopic equipment 5 drives the sliding table 4 to move towards the upper ends of the two clamps 12, the housing 6 and the cutting wheel 8 can be driven to synchronously move, the driving motor 9 is started at the moment, the driving motor 9 can drive the cutting wheel 8 to rotate to complete cutting action, when the cutting wheel 8 moves to the position right above the two clamps 12, the telescopic equipment 5 stops moving, the cutting wheel 8 can cut the upper end of the tubular aluminum alloy section, and the upper end of the aluminum alloy section is cut through;

during the movement of the sliding table 4, the sliding table 4 compresses the first spring 24, the sliding plate 23 is pressed by the first spring 24, when the sliding table 4 drives the cutting wheel 8 to move to the cutting station, the sliding table 4 drives the trigger block 29 to move to the position right above the wedge block 26, the trigger block 29 and the permanent magnet in the wedge block 26 generate repulsive force, so that the wedge block 26 is completely pushed into the second sliding groove 25 by repulsive force, the sliding plate 23 is not limited by the wedge block 26 any more, the sliding plate 23 drives the rack 20 to slide in a direction away from the first spring 24 under the action of the pressing of the first spring 24, the rack 20 drives the third transmission shaft 18 to rotate through the driven gear 21, the third transmission shaft 18 drives the second transmission shaft 16 to rotate through the two meshed bevel gears 19, the second transmission shaft 16 drives one of the sleeves 11 to rotate through the worm gear 17, one of the sleeves 11 drives the second gear 15 to rotate through the first gear 14, the second gear 15 drives the other second gear 15 to rotate through the first transmission shaft 13, so that the other sleeve 11 is driven to rotate, the two rotating sleeves 11 drive the inner aluminum alloy section to rotate slowly, at the moment, the cutting wheel 8 can cut the outer wall of the aluminum alloy section in a winding way, the cutting work of the aluminum alloy section can be completed, in the cutting process, the cutting depth of the cutting wheel 8 is low, thus the noise generated due to friction can be effectively reduced, the cutting efficiency is greatly improved after friction is reduced, the burrs generated by cutting can be inclined towards the middle part of the tubular aluminum alloy section through the winding type cutting, meanwhile, part of burrs can be ground by the cutting wheel 8, the quality of the aluminum alloy section can be effectively improved, the attractiveness of the aluminum alloy door and window frame can be indirectly improved, and when the cutting is completed, the sliding table 4 and the cutting wheel 8 are driven to reversely slide and reset through the telescopic equipment 5, the sliding plate 23 is also pulled to the initial position by the first spring 24, and when the wedge-shaped block 26 is aligned with the clamping groove 27 again, the second spring 28 drives the wedge-shaped block 26 to automatically clamp into the clamping groove 27.

When cutting is finished, the driving motor 9 is turned off, and the cutting wheel 8 continuously rotates for a period of time under the action of inertia force; when the housing 6 moves to the upper ends of the two sleeves 11, the ejector rod 51 is inserted into a gap between the vertical plate 32 and the housing 6, the vertical plate 32 is pushed by the ejector rod 51 to be far away from the housing 6, the vertical plate 32 drives the second friction plate 37 to be far away from the first friction plate 36 through the fourth transmission shaft 38, when the rotating shaft 7 drives the cutting blade 8 to rotate, the second friction plate 37 cannot rotate, after cutting is finished, namely, when the housing 6 is reversely slid and reset, the ejector rod 51 cannot push the vertical plate 32, the third spring 35 drives the vertical plate 32 to slide and reset in the direction, the vertical plate 32 drives the second friction plate 37 to push against the first friction plate 36, at this time, because the cutting wheel 8 which rotates by inertia drives the second friction plate 37 to rotate through the first friction plate 36, the second friction plate 37 drives the driving shaft 39 to rotate through the chain transmission 40, the driving shaft 39 drives the cooling blade 41 to rotate in the cooling blade 31, the cooling blade 31 is exhausted outwards, the housing 6 can absorb air through the lower port, the flowing air flow wheel 8 can effectively slide and reset in the direction, and the dust can be conveniently cut and the dust can be filtered, and the dust can be removed, and the dust can be timely removed, and the dust can be filtered, and the dust can be removed.

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

Claims (10)

1. Cutting device is used in processing of aluminum alloy door and window frame, including cutting board (1), its characterized in that still includes:

two struts (2) which are fixedly connected to the cutting table (1),

a transverse sliding rod (3) is fixedly connected between the two support posts (2), a sliding table (4) is slidably arranged on the transverse sliding rod (3), a telescopic device (5) is fixedly arranged on one support post (2), and a telescopic end of the telescopic device (5) is fixedly connected with the sliding table (4);

a cover shell (6) with a downward opening is fixedly connected to the sliding table (4),

the cutting machine comprises a cover shell (6), a cutting wheel (8) and a sliding table (4), wherein the cutting wheel (8) is rotatably arranged in the cover shell (6) through a rotating shaft (7), and a driving motor (9) for driving the rotating shaft (7) to rotate is fixedly arranged on the sliding table (4);

two support plates (10) which are symmetrical from front to back are fixedly arranged on the cutting table (1),

the two support plates (10) are respectively connected with a sleeve (11) in a rotating mode, clamps (12) are respectively fixedly installed on the two sleeves (11), and the transverse sliding rod (3) is provided with a rotating mechanism for driving the two sleeves (11) to rotate.

2. The cutting device for processing an aluminum alloy door and window frame according to claim 1, wherein the rotation mechanism comprises:

a first transmission shaft (13) rotatably connected between the two support plates (10), a first gear (14) fixedly arranged on the outer walls of the two sleeves (11),

the two ends of the first transmission shaft (13) are fixedly provided with second gears (15) meshed with the first gears (14), the lower end of the transverse sliding rod (3) is slidably connected with a sliding plate (23) through a first sliding groove (22), the sliding plate (23) is elastically connected with the sliding table (4) through a first spring (24), a clamping and locking assembly matched with the sliding plate (23) is arranged in the first sliding groove (22), and the sliding plate (23) is connected with one of the sleeves (11) through the transmission assembly.

3. The cutting device for processing an aluminum alloy door and window frame according to claim 2, wherein the transmission assembly comprises:

a second transmission shaft (16) rotatably arranged on one of the support plates (10), the second transmission shaft (16) is connected with the sleeve (11) through a worm gear (17),

the support column (2) is rotatably connected with a third transmission shaft (18), the lower end of the third transmission shaft (18) is connected with a second transmission shaft (16) through two meshed bevel gears (19), a driven gear (21) is fixedly arranged at the upper end of the third transmission shaft (18), and a rack (20) meshed with the driven gear (21) is fixedly arranged on the sliding plate (23).

4. The cutting device for processing an aluminum alloy door and window frame according to claim 2, wherein the latch assembly comprises:

a second sliding groove (25) arranged at the upper end of the sliding plate (23), a wedge-shaped block (26) is connected in a sliding way in the second sliding groove (25),

the novel sliding table is characterized in that the wedge-shaped block (26) is elastically connected with the inner bottom of the second sliding groove (25) through a second spring (28), a clamping groove (27) matched with the wedge-shaped block (26) is formed in the first sliding groove (22), a triggering block (29) matched with the clamping groove (27) is fixedly connected onto the sliding table (4), permanent magnets are fixedly arranged in the triggering block (29) and the wedge-shaped block (26), the opposite magnetic poles of the permanent magnets are identical, the clamping groove (27) is located at the upper ends of the two sleeves (11), and a hydraulic buffer (30) is fixedly arranged between the sliding plate (23) and the inner wall of the first sliding groove (22).

5. The cutting device for processing the aluminum alloy door and window frame according to claim 1, wherein the upper end side wall of the housing (6) is provided with a radiating pipe (31) communicated with the radiating pipe, the side wall of the housing (6) is provided with a telescopic mechanism connected with a vertical plate (32),

the heat dissipation device comprises a heat dissipation pipe (31), a vertical plate (32) and a driving shaft (39) extending into the heat dissipation pipe (31) are rotatably connected to the side wall of the upper end of the vertical plate (32), heat dissipation fan blades (41) are fixedly installed on the driving shaft (39), a fourth driving shaft (38) coaxial with a rotating shaft (7) is rotatably connected to the side wall of the lower end of the vertical plate (32), the fourth driving shaft (38) is connected with the driving shaft (39) through a chain driving shaft (40), a first friction disc (36) facing the fourth driving shaft (38) is fixedly installed at one end of the rotating shaft (7), and a second friction disc (37) matched with the first friction disc (36) is fixedly installed on the fourth driving shaft (38).

6. The cutting device for processing an aluminum alloy door and window frame according to claim 5, wherein the telescopic mechanism comprises:

the guide rod (33) is fixedly arranged on the outer wall of the housing (6), the vertical plate (32) is connected to the guide rod (33) in a sliding way, the vertical plate (32) is elastically connected with the outer wall of the housing (6) through a third spring (35), one of the support posts (2) is fixedly connected with a push rod (51) matched with the vertical plate (32),

when the housing (6) moves to the upper end of the sleeve (11), the ejector rod (51) pushes the vertical plate (32) up in a direction away from the housing (6).

7. The cutting device for processing the aluminum alloy door and window frame according to claim 6, wherein a first polygonal rod (53) is fixedly connected to an output shaft of the driving motor (9), a sliding tube (54) is slidingly connected to the outer wall of the first polygonal rod (53),

the sliding tube (54) and the opposite ends of the rotating shaft (7) are fixedly provided with third friction plates (55), the opposite surfaces of the two third friction plates (55) are respectively provided with gear teeth, the outer wall of the sliding tube (54) is fixedly connected with a push plate (52), and the push plate (52) is fixedly connected with a vertical plate (32) through a connecting rod (63).

8. The cutting device for processing the aluminum alloy door and window frames according to claim 5, wherein the inner wall of the housing (6) is fixedly provided with a blowing nozzle (50), the air outlet of the blowing nozzle (50) faces the edge of the cutting wheel (8),

the air outlet of the blowing nozzle (50) faces the radiating pipe (31), and an air supply assembly for supplying air to the blowing nozzle (50) is arranged on the second friction disc (37).

9. The cutting device for processing an aluminum alloy door and window frame according to claim 8, wherein the air supply assembly comprises:

a plurality of third sliding grooves (42) arranged on the second friction plate (37), sliding blocks (43) are connected in the third sliding grooves (42) in a sliding way, the sliding blocks (43) are elastically connected with the inner wall of the third sliding grooves (42) through fourth springs (44),

the novel air blowing device is characterized in that cambered surface convex blocks (45) matched with a plurality of sliding blocks (43) are fixedly arranged on the first friction disc (36), an air suction pipe (47) and an air exhaust pipe (46) which are communicated with the third sliding groove (42) are arranged on the second friction disc (37), an air conveying pipe (48) communicated with the air exhaust pipe (46) is fixedly arranged in the fourth transmission shaft (38), and the air conveying pipe (48) is communicated with the air blowing nozzle (50) through a connecting pipe (49).

10. The cutting device for processing the aluminum alloy door and window frame according to claim 5, wherein the filter element (56) is detachably installed in the radiating pipe (31).