CN115464208B

CN115464208B - Multifunctional platform for processing aluminum profile

Info

Publication number: CN115464208B
Application number: CN202211122903.8A
Authority: CN
Inventors: 罗斌; 刘艳平
Original assignee: Jiangsu Gaoka Light Alloy Co ltd
Current assignee: Jiangsu Gaoka Light Alloy Co ltd
Priority date: 2022-09-15
Filing date: 2022-09-15
Publication date: 2023-10-20
Anticipated expiration: 2042-09-15
Also published as: CN115464208A

Abstract

The application relates to the technical field of aluminum profile processing equipment, in particular to a multifunctional platform for aluminum profile processing, which comprises a working platform, a clamping device and a cutter, wherein the clamping device is arranged on the working platform and is used for clamping a workpiece, the workpiece is provided with a first axis, the cutter is arranged on the working platform and can rotate around the first axis to circularly cut the workpiece, the cutter can rotate around a second axis to cut the workpiece, and the second axis is not overlapped with the first axis. The cutter can rotate around the first axis and the second axis, and the second axis is not coincident with the first axis so as to cut the workpiece, so that on one hand, the size of the cutter is smaller, and the cost is reduced and the risk of cutter breakage is reduced; on the other hand, the cutter can finish beveling at any angle, and the precision is improved and the complex cutting requirement is met.

Description

Multifunctional platform for processing aluminum profile

Technical Field

The application relates to the technical field of aluminum profile processing equipment, in particular to a multifunctional platform for aluminum profile processing.

Background

The density of the aluminum profile is only 2.7g/cm3, about 1/3 of the density of steel, copper or brass (7.83 g/cm3,8.93g/cm3, respectively). Aluminum exhibits excellent corrosion resistance under most environmental conditions, including in air, water (or brine), petrochemistry, and many chemical systems. Because of the good properties of aluminum, aluminum profiles of various shapes are widely used in various indoor homes and outdoor equipment.

And for the round cast rod in the aluminium alloy course of working, in order to increase the extruded convenience, consequently need cut into the segmentation with raw and other materials aluminium bar, but in the cutting process, can produce a large amount of sawdust and lead to later stage collection comparatively troublesome to the sawdust splashes and hurts the people easily, simultaneously, when cutting the aluminium bar through the circular saw, the radius of saw bit is greater than the diameter of aluminium bar, has increased the cracked risk of saw bit when increasing the cost.

For example, chinese patent CN113172275B discloses an aluminum bar cutting device with sawdust recycling function based on aluminum profile processing, and the aluminum bar cutting device includes the connecting plate, fixedly on the right side terminal surface that the connecting plate is close to the downside terminal surface be provided with the bottom plate, the upside terminal surface of bottom plate reaches fixedly between the right side terminal surface of connecting plate be provided with the backup pad of fore-and-aft symmetry, be provided with the back-and-forth supporting slot that runs through and be used for placing the aluminum bar in the backup pad, be provided with the spout that the opening upwards and right in the bottom plate, slidable is provided with the slide in the spout, be provided with the storage tank that runs through from top to bottom in the slide, be provided with respectively in the front and back side inner wall of spout drive the cutting feeding device of slide side by side, fixedly on the upside terminal surface of slide be provided with saw bit protection casing.

But in the prior art, the aluminum bar is often processed by adopting a mode of obliquely and directly cutting by a cutter or manually scribing and manually cutting the aluminum bar, so that the yield is low and the aluminum bar cannot adapt to complex cutting requirements.

Disclosure of Invention

The applicant finds that in the prior art, the aluminum bar is often beveled by adopting a cutter tilting and straight cutting mode, and the cutting requirement is met to a certain extent, but the radius of the cutter is often too large, so that the cost is increased and the risk of cutter breakage is increased; the method of manually scribing and manually cutting is adopted, the precision is low, burrs on the section of the cut aluminum bar are more, and the subsequent processes are required to be added for treatment, so that time and labor are wasted; moreover, the angle of the cutter cannot be freely adjusted in the two modes, and the complex cutting requirements cannot be adapted.

Based on the above, it is necessary to provide a multifunctional platform for processing aluminum profiles, aiming at the problems of the existing cutting equipment.

The above purpose is achieved by the following technical scheme:

a multifunctional platform for processing aluminum profiles, comprising:

a working platform;

the clamping device is arranged on the working platform and used for clamping a workpiece, and the workpiece is provided with a first axis;

the cutter is arranged on the working platform, the cutter can rotate around the first axis to circularly cut the workpiece, the cutter can rotate around the second axis to cut the workpiece, and the second axis is not overlapped with the first axis.

In one embodiment, the rotary cutting device further comprises a moving assembly, an angle adjusting assembly, a revolution cutting assembly and a rotation cutting assembly, wherein the moving assembly is used for changing the position of the cutter; the angle adjusting component changes the included angle between the cutter and the first axis; the revolution cutting assembly is used for providing driving force for the cutter to move around the first axis; the autorotation cutting assembly is used for providing driving force for the cutter to move around the second axis.

In one embodiment, the moving assembly includes a slide seat slidably disposed on the work platform; the angle adjusting assembly comprises an annular slideway, a first sliding block, a first driving piece, a second driving piece and a first transmission piece, wherein the annular slideway can be rotatably arranged on the sliding seat, one end of the first sliding block can be rotatably arranged on the annular slideway, and the other end of the first sliding block can be slidably arranged on the working platform; the first driving piece is arranged on the first sliding block, the first driving piece provides driving force for rotating the annular slideway, the second driving piece is arranged on the annular slideway, and the first transmission piece is arranged on the second driving piece; the revolution cutting assembly comprises an annular sliding block and a second transmission piece, the annular sliding block can be rotatably arranged on the annular slideway, and the second transmission piece is arranged on the annular sliding block; the first transmission piece can drive the second transmission piece to move; the autorotation cutting assembly comprises a third driving piece, a fourth driving piece, a base and a sliding block, and the base can be rotatably arranged on the annular sliding block; the sliding block can be arranged on the base in a sliding manner; the third driving piece is arranged on the sliding block, the cutter is arranged on the third driving piece, and the third driving piece provides driving force for movement of the cutter; the fourth driving piece is arranged on the base and provides driving force for the sliding block to move.

In one embodiment, the autorotation cutting assembly further comprises a fifth driving member and a sixth driving member, wherein the fifth driving member and the sixth driving member are used for providing driving force for rotating the base.

In one embodiment, a seventh driving piece, an eighth driving piece, a first screw rod and a second screw rod are arranged on the working platform, the first screw rod and the second screw rod can be rotatably arranged on the working platform, the seventh driving piece provides driving force for rotation of the first screw rod, and the eighth driving piece provides driving force for rotation of the second screw rod; the sliding seat is detachably connected with the first screw rod and the second screw rod.

In one embodiment, the mobile assembly further comprises a dial disposed on the sliding seat.

In one embodiment, the angle adjustment assembly further comprises a collection trough disposed on the annular slide, the collection trough being configured to collect debris cut by the cutter.

In one embodiment, the angle adjustment assembly further comprises a collection trough, the angle adjustment assembly further comprising a first water outlet disposed on the collection trough; the annular sliding block is provided with a second water outlet; the collecting groove and the annular sliding block are filled with fluid; when the first water outlet and the second water outlet are communicated, fluid flows into the collecting groove from the annular sliding block.

In one embodiment, the number of cutters and the number of self-rotating cutter assemblies are the same and are at least two.

The beneficial effects of the application are as follows:

the application relates to a multifunctional platform for processing aluminum profiles, which comprises a working platform, a clamping device and a cutter, wherein the clamping device is arranged on the working platform and is used for clamping a workpiece, the workpiece is provided with a first axis, the cutter is arranged on the working platform and can rotate around the first axis to circularly cut the workpiece, the cutter can rotate around a second axis to cut the workpiece, and the second axis is not overlapped with the first axis. The cutter can rotate around the first axis and the second axis, and the second axis is not coincident with the first axis so as to cut the workpiece, so that on one hand, the size of the cutter is smaller, and the cost is reduced and the risk of cutter breakage is reduced; on the other hand, the cutter can finish beveling at any angle, and the precision is improved and the complex cutting requirement is met.

Through setting up the collecting vat, and then can carry out timely recovery to the piece that produces in the cutting process.

By arranging the first water outlet and the second water outlet, the chips are timely cooled and timely recovered.

Drawings

Fig. 1 is a schematic perspective view of a multifunctional platform for processing aluminum profiles according to an embodiment of the present application;

fig. 2 is a schematic perspective view of a working platform of the multifunctional platform for processing aluminum profiles according to an embodiment of the present application;

fig. 3 is a schematic perspective view of a cutting device of a multifunctional platform for processing aluminum profiles according to an embodiment of the application;

fig. 4 is a schematic perspective view of a moving assembly of a multifunctional platform for processing aluminum profiles according to an embodiment of the present application;

FIG. 5 is a schematic perspective view illustrating a cross-sectional view of an angle adjusting assembly of a multifunctional platform for aluminum profile processing according to an embodiment of the present application;

fig. 6 is a schematic perspective view of a cutting assembly of a multifunctional platform for processing aluminum profiles according to an embodiment of the present application;

fig. 7 is a schematic view of a perspective sectional view of a revolution cutting assembly of a multifunctional platform for processing aluminum profiles according to an embodiment of the present application;

fig. 8 is a schematic perspective view of a rotation cutting assembly of a multifunctional platform for processing aluminum profiles according to an embodiment of the present application;

fig. 9 is a schematic diagram of the operation of a cutter of the multifunctional platform for processing aluminum profiles according to an embodiment of the present application;

fig. 10 is a second working schematic diagram of a cutter of the multifunctional platform for processing aluminum profiles according to an embodiment of the present application;

fig. 11 is a third working schematic diagram of a cutter of a multifunctional platform for processing aluminum profiles according to an embodiment of the present application.

Wherein:

100. a working platform; 101. a first motor; 1011. a first screw rod; 102. a clamping device; 103. a second motor; 1031. a second screw rod; 104. a first slideway; 1041. a second slideway; 105. a third slideway;

200. a cutting device;

210. a moving assembly; 211. a dial; 212. a first through hole; 213. a second through hole; 214. a sliding seat;

220. an angle adjustment assembly; 221. a rotating shaft; 222. a collection tank; 223. an annular slideway; 224. a first water outlet; 225. a first slider; 226. a third motor; 227. a first gear; 228. a fourth motor;

230. revolution cutting assembly; 231. an annular slide block; 232. a second gear; 233. a second water outlet; 234. a mounting groove; 235. a rotation hole; 236. a ring groove;

240. a self-rotating cutting assembly; 241. a cutter; 242. a fifth motor; 243. a sliding block; 244. a base; 245. a first cylinder; 246. a second cylinder; 247. a column; 248. a third cylinder;

300. and (3) a round tube.

Detailed Description

The present application will be further described in detail below with reference to examples, which are provided to illustrate the objects, technical solutions and advantages of the present application. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

The numbering of components herein, such as "first," "second," etc., is used merely to distinguish between the described objects and does not have any sequential or technical meaning. The term "coupled" as used herein includes both direct and indirect coupling (coupling), unless otherwise indicated. In the description of the present application, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

In the present application, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

As shown in fig. 1 to 11, the multifunctional platform for processing aluminum profiles according to an embodiment of the present application is used for processing aluminum profiles, and for convenience of description, a workpiece is named as a round pipe 300; in this embodiment, the multifunctional platform for processing the aluminum profile comprises a working platform 100, a clamping device 102, a cutting device 200 and a cutter 241; the working platform 100 is provided with a first slideway 104, a second slideway 1041 and a third slideway 105; the clamping device 102 is fixedly connected to the working platform 100 through bolts, and the clamping device 102 is used for clamping one end of the round tube 300; the axis of the circular tube 300 is a first axis, the axis of the cutter 241 is a second axis, the cutter 241 can rotate around the first axis to round the circular tube 300, the cutter 241 can rotate around the second axis to cut the circular tube 300, and the second axis is not coincident with the first axis.

By arranging the cutters 241 to rotate around the first axis and the second axis, and the second axis is not coincident with the first axis so as to cut the round tube 300, on one hand, the size of the cutter 241 is smaller, and the cost is reduced and the risk of breakage of the cutters 241 is reduced; on the other hand, the cutter 241 can finish beveling at any angle, and complex cutting requirements are met while the precision is improved.

It is understood that the round tube 300 may be made of metal material such as aluminum, copper or iron, or nonmetal material such as wood, polyethylene, etc., wherein the round tube 300 is preferably a rod tube made of aluminum.

It is understood that the application can be used for cutting rod-shaped materials, and can also be used for cutting materials with any shape and any angle, such as rectangular, triangular and other material shapes.

It will be appreciated that the clamping device 102 may take the form of any of a three jaw chuck, a four jaw chuck, an air chuck, or a hydraulic chuck.

In some embodiments, the multifunctional platform for processing aluminum profiles comprises a moving assembly 210, an angle adjusting assembly 220, a revolution cutting assembly 230 and a rotation cutting assembly 240, wherein the moving assembly 210 is used for adjusting the cutting position of the cutter 241, and the angle adjusting assembly 220 is used for adjusting the included angle between the cutter 241 and the axis of the round tube 300; the revolution cutting assembly 230 and the rotation cutting assembly 240 are used for driving the cutter 241 to rotate around the axis of the circular tube 300 and simultaneously rotate around the axis thereof, thereby completing the cutting of the circular tube 300 through the cutter 241.

In some embodiments, the moving assembly 210 includes a sliding seat 214, the angle adjusting assembly 220 includes an annular slideway 223, a first slider 225, a first driving member for adjusting an included angle between the cutter 241 and the axis of the circular tube 300, a second driving member for providing a driving force for rotating the cutter 241 around the axis of the circular tube 300, and a first driving member for transmitting the driving force of the second driving member, the revolution cutting assembly 230 includes an annular slider 231 and a second driving member for transmitting the driving force of the first driving member, and the rotation cutting assembly 240 includes a third driving member, a fourth driving member, a base 244, a sliding block 243 and an upright post 247; in this embodiment, the first driving member is a third motor 226, the second driving member is a fourth motor 228, the first driving member is a first gear 227, the second driving member is a second gear 232, the third driving member is a fifth motor 242, and the fourth driving member is a second cylinder 246; the sliding seat 214 is provided with a first through hole 212 and a second through hole 213, and the sliding seat 214 can be sleeved at the first slide 104 and the second slide 1041 in a sliding manner; the rotating shaft 221 is fixedly arranged on the annular slideway 223, the annular slideway 223 can be rotatably connected to the second through hole 213 through the rotating shaft 221, the third motor 226 is fixedly connected to the first slide block 225 through a bolt, one end of the first slide block 225 can be arranged at the third slideway 105, the other end of the first slide block 225 can be rotatably connected to the annular slideway 223, and the third motor 226 provides driving force for the rotation of the annular slideway 223; the fourth motor 228 is fixedly connected to the annular slide way 223 through a bolt, and the first gear 227 is fixedly connected to a motor shaft of the fourth motor 228; the annular slide block 231 is provided with a mounting groove 234, a rotating hole 235 and a ring groove 236, the annular slide block 231 is coaxially sleeved in the annular slide way 223 in a rotatable manner, the second gear 232 is fixedly connected to the annular slide block 231, and the second gear 232 is always meshed with the first gear 227; the fifth motor 242 is fixedly connected to the sliding block 243 through a bolt, the cutter 241 is fixedly connected to a motor shaft of the fifth motor 242, and the fifth motor 242 provides a driving force for rotation of the cutter 241; the upright post 247 is fixedly connected to the base 244, and the base 244 is rotatably connected to the mounting groove 234 by the connection of the upright post 247 to the rotation hole 235; the sliding block 243 is slidably coupled to the base 244, and the second cylinder 246 is fixedly coupled to the base 244, and the second cylinder 246 provides a driving force for the sliding block 243 to move.

In some embodiments, the rotary cutting assembly 240 further includes a fifth drive member, which in this embodiment is the first cylinder 245, and a sixth drive member, which in this embodiment is the third cylinder 248; the first air cylinder 245 and the third air cylinder 248 are fixedly connected to the annular slider 231 and symmetrically arranged with respect to the base 244, and the first air cylinder 245 and the third air cylinder 248 provide driving force for the rotation of the base 244 so as to finely adjust the cutter 241.

In some embodiments, the working platform 100 is provided with a seventh driving element, an eighth driving element, a first screw 1011 and a second screw 1031, where the seventh driving element is the first motor 101 and the eighth driving element is the second motor 103; the first motor 101 and the second motor 103 are fixedly connected to the working platform 100 through bolts, wherein the first motor 101 and the second motor 103 are symmetrically arranged relative to the working platform 100, the clamping device 102 is arranged between the first motor 101 and the second motor 103, the first screw 1011 can be rotatably arranged on the working platform 100 under the driving of the first motor 101, and the second screw 1031 can be rotatably arranged on the working platform 100 under the driving of the second motor 103; the sliding seat 214 is sleeved on the first screw rod 1011 and the second screw rod 1031 through the first through hole 212, and the sliding seat 214 is in threaded connection with the first screw rod 1011 and the second screw rod 1031; the first motor 101 and the second motor 103 drive the first screw 1011 and the second screw 1031 to rotate, and the first screw 1011 and the second screw 1031 drive the sliding seat 214 to slide along the first slide 104 and the second slide 1041.

In some embodiments, the moving assembly 210 further includes a dial 211, where the dial 211 and the second through hole 213 are coaxially disposed on the sliding seat 214, and an included angle between an axis of the annular slide 223 and an axis of the circular tube 300 is determined by indication of the dial 211, so as to determine an included angle between the cutter 241 and the circular tube 300.

In some embodiments, the angle adjustment assembly 220 further includes a collection trough 222, the collection trough 222 being fixedly disposed on an annular slide 223, and the cut debris being collected by the collection trough 222.

In some embodiments, the angle adjustment assembly 220 further includes a first water outlet 224, the first water outlet 224 being disposed on the collection trough 222, and a second water outlet 233 being disposed on the annular slider 231; the collecting tank 222 and the annular slide block 231 are filled with a certain amount of cooling liquid; chips are continuously generated during the cutting process, and part of the chips can directly fall into the collecting tank 222 to be cooled by the cooling liquid; some of the chips adhere to the inner wall surface of the annular slider 231, and the chips are cooled and collected in the cooling liquid while passing through the cooling liquid, and when the annular slider 231 rotates to the second water outlet 233 to communicate with the first water outlet 224, the chips in the annular slider 231 are brought together into the collection tank 222 by the cooling liquid, thereby completing the collection of the chips.

In some embodiments, the number of the autorotation cutting assemblies 240 is two, i.e. the cutters 241 are two, and the structure is the same and the cutter assemblies are disposed 180 degrees relatively, so as to improve the cutting efficiency of the circular tube 300.

It will be appreciated that multiple (greater than two) sets of spinning cutting assemblies 240 may be provided to improve the cutting efficiency of the tubular 300.

In combination with the above embodiment, the use principle and working process of the embodiment of the present application are as follows:

the multifunctional platform for processing the aluminum profile comprises a working platform 100 and a cutting device 200, and for convenience of description, a workpiece to be cut is named as a circular tube 300; the working platform 100 is provided with a clamping device 102, and the clamping device 102 is used for clamping the round tube 300; the cutting device 200 comprises a moving assembly 210, an angle adjusting assembly 220, a revolution cutting assembly 230 and a rotation cutting assembly 240, wherein the moving assembly 210 is used for adjusting the cutting position of the cutter 241, and the angle adjusting assembly 220 is used for adjusting the included angle between the cutter 241 and the axis of the circular tube 300; the revolution cutting assembly 230 and the rotation cutting assembly 240 are used for driving the cutter 241 to rotate around the axis of the annular slideway 223 and simultaneously rotate around the axis thereof, so that the cutter 241 can cut the round tube 300.

Before cutting, a certain amount of cooling liquid is injected into both the collecting tank 222 and the annular slider 231; clamping one end of the circular tube 300 by the clamping device 102, so as to limit the movement and rotation of the circular tube 300; the first motor 101 and the second motor 103 are started, and the first motor 101 and the second motor 103 drive the first screw 1011 and the second screw 1031 to rotate, so as to drive the sliding seat 214 to move towards or away from the round tube 300, thereby adjusting the cutting position of the cutter 241.

When the circular tube 300 needs to be vertically cut, the third motor 226 is started to drive the annular slide way 223 to rotate around the axis of the rotating shaft 221, and the axis of the annular slide way 223 and the axis of the circular tube 300 can be determined to coincide or nearly coincide through naked eyes or indication through the dial 211; the first and third cylinders 245, 248 are then activated to rotate the base 244 about the axis of the post 247 until the side of the base 244 is parallel to the side of the annular slider 231, at which point the cutter 241 is perpendicular to the axis of the barrel 300.

Starting the second cylinder 246 to drive the sliding block 243 to move in a direction away from the base 244 until the cutter 241 is abutted against the outer circumferential wall surface of the circular tube 300; simultaneously starting the fourth motor 228 and the fifth motor 242, so that the cutter 241 can rotate around the axis (or the first axis) of the annular slide way 223 and simultaneously rotate around the axis of the cutter, thereby cutting the round tube 300; meanwhile, under the action of electric control, the second cylinder 246 drives the sliding block 243 to move continuously in the direction away from the base 244, so that the cutter 241 can cut the round tube 300 continuously until the round tube 300 is cut off, and meanwhile, the cut chips are collected through the collecting groove 222.

When the circular tube 300 needs to be obliquely cut (a certain included angle is required between the cutter 241 and the axis of the circular tube 300), the third motor 226 is started to drive the annular slideway 223 to rotate around the axis of the rotating shaft 221, and the included angle between the axis of the annular slideway 223 and the axis of the circular tube 300 can be determined by visual observation or indication through the dial 211; then, the first air cylinder 245 and the third air cylinder 248 are started to drive the base 244 to rotate around the axis of the upright post 247, so as to finely adjust the cutter 241, and at this time, a preset included angle is formed between the cutter 241 and the axis of the round tube 300.

Starting the second cylinder 246 to drive the sliding block 243 to move in a direction away from the base 244 until the cutter 241 is abutted against the outer circumferential wall surface of the round tube 300 (because the axis of the annular sliding block 231 and the axis of the round tube 300 have a certain included angle at this time, the second cylinder 246 can be controlled respectively, so that the cutter 241 is abutted against the outer circumferential wall surface of the round tube 300); simultaneously starting the fourth motor 228 and the fifth motor 242, so that the cutter 241 can rotate around the axis (or the first axis) of the annular slide way 223 and simultaneously rotate around the axis of the cutter, thereby cutting the round tube 300; meanwhile, under the action of electric control, the second air cylinder 246 drives the sliding block 243 to continuously move in the direction away from the base 244, so that the cutter 241 can continuously cut the round tube 300 until the round tube 300 is cut off; while the cut-off chips are collected by the collection trough 222.

Chips are continuously generated during the cutting process, and part of the chips can directly fall into the collecting tank 222 to be cooled by the cooling liquid; some of the chips adhere to the inner wall surface of the annular slider 231, and the chips are cooled and collected in the cooling liquid while passing through the cooling liquid, and when the annular slider 231 rotates to the second water outlet 233 to communicate with the first water outlet 224, the chips in the annular slider 231 are brought together into the collection tank 222 by the cooling liquid, thereby completing the collection of the chips.

After the cutting is completed, the cutting surface of the round tube 300 may have burrs, at this time, the first motor 101 and the second motor 103 drive the sliding seat 214 to move, and further drive the cutter 241 to abut against the cutting surface of the round tube 300, at this time, the fourth motor 228 and the fifth motor 242 are started, so that the cutter 241 can rotate around the axis (or the first axis) of the annular slideway 223 while rotating around the axis, and further grind the cutting surface of the round tube 300.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The foregoing examples illustrate only a few embodiments of the application and are described in detail herein without thereby limiting the scope of the application. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims

1. The utility model provides an aluminium alloy processing is with multi-functional platform which characterized in that includes:

a working platform;

the cutter is arranged on the working platform, can rotate around the first axis to circularly cut the workpiece, can rotate around the second axis to cut the workpiece, and is not overlapped with the first axis;

the rotary cutting device also comprises a moving assembly, an angle adjusting assembly, a revolution cutting assembly and a rotation cutting assembly, wherein the moving assembly is used for changing the position of the cutter; the angle adjusting component changes the included angle between the cutter and the first axis; the revolution cutting assembly is used for providing driving force for the cutter to move around the first axis; the autorotation cutting assembly is used for providing driving force for the cutter to move around the second axis;

the moving assembly comprises a sliding seat which can be arranged on the working platform in a sliding manner; the angle adjusting assembly comprises an annular slideway, a first sliding block, a first driving piece, a second driving piece and a first transmission piece, wherein the annular slideway can be rotatably arranged on the sliding seat, one end of the first sliding block can be rotatably arranged on the annular slideway, and the other end of the first sliding block can be slidably arranged on the working platform; the first driving piece is arranged on the first sliding block, the first driving piece provides driving force for rotating the annular slideway, the second driving piece is arranged on the annular slideway, and the first transmission piece is arranged on the second driving piece; the revolution cutting assembly comprises an annular sliding block and a second transmission piece, the annular sliding block can be rotatably arranged on the annular slideway, and the second transmission piece is arranged on the annular sliding block; the first transmission piece can drive the second transmission piece to move; the autorotation cutting assembly comprises a third driving piece, a fourth driving piece, a base and a sliding block, and the base can be rotatably arranged on the annular sliding block; the sliding block can be arranged on the base in a sliding manner; the third driving piece is arranged on the sliding block, the cutter is arranged on the third driving piece, and the third driving piece provides driving force for movement of the cutter; the fourth driving piece is arranged on the base and provides driving force for the sliding block to move.

2. The multifunctional platform for processing aluminum profiles according to claim 1, wherein the autorotation cutting assembly further comprises a fifth driving member and a sixth driving member, wherein the fifth driving member and the sixth driving member are both used for providing driving force for rotating the base.

3. The multifunctional platform for aluminum profile machining according to claim 1, wherein a seventh driving piece, an eighth driving piece, a first screw rod and a second screw rod are arranged on the working platform, the first screw rod and the second screw rod are rotatably arranged on the working platform, the seventh driving piece provides driving force for rotation of the first screw rod, and the eighth driving piece provides driving force for rotation of the second screw rod; the sliding seat is detachably connected with the first screw rod and the second screw rod.

4. The multifunctional platform for processing aluminum profiles according to claim 1, wherein the moving assembly further comprises a dial plate, the dial plate being disposed on the sliding seat.

5. The multifunctional platform for aluminum profile machining according to claim 1, wherein the angle adjusting assembly further comprises a collection trough disposed on the annular slide for collecting chips cut by the cutter.

6. The multifunctional platform for aluminum profile machining according to claim 5, wherein the angle adjusting assembly further comprises a first water outlet, the first water outlet being arranged on the collecting tank; the annular sliding block is provided with a second water outlet; the collecting groove and the annular sliding block are filled with fluid; when the first water outlet and the second water outlet are communicated, fluid flows into the collecting groove from the annular sliding block.

7. The multifunctional platform for processing aluminum profiles according to claim 1, wherein the number of the cutters and the number of the autorotation cutting assemblies are the same and at least two.