CN115625373A

CN115625373A - Two-way cutting device of section bar

Info

Publication number: CN115625373A
Application number: CN202211538702.6A
Authority: CN
Inventors: 刘青; 郑梁基; 黄煜南
Original assignee: Guangdong Chuangsheng Metal Structure Co ltd
Current assignee: Guangdong Chuangsheng Intelligent Manufacturing Co.,Ltd.
Priority date: 2022-12-02
Filing date: 2022-12-02
Publication date: 2023-01-20
Anticipated expiration: 2042-12-02
Also published as: CN115625373B

Abstract

The invention relates to the technical field of profile processing, in particular to a profile bidirectional cutting device. The bidirectional cutting device for the section comprises a connecting table and the like; the middle part of the upper surface of the connecting table is connected with a positioning system for positioning the motor shell aluminum profile; the positioning system is connected with a plurality of positioning blocks for limiting the movement of the cooling fins of the aluminum profile of the motor shell; the positioning blocks are respectively connected with a first scraper used for removing burrs. According to the invention, when the motor shell aluminum profile moves, all the cooling fins are limited by the positioning blocks, so that the problems that as a plurality of cooling fins are distributed on the outer ring surface of the motor shell aluminum profile at equal intervals, and each cooling fin is thin, the cooling fins are easy to bend and deform during cutting, in the prior art, the motor shell aluminum profile is clamped by the clamping mechanism, and then the motor shell aluminum profile is cut by the cutting blade rotating at a high speed, so that the cooling fins are easy to bend and deform, and the cutting efficiency is low are solved.

Description

Two-way cutting device of section bar

Technical Field

The invention relates to the technical field of section bar processing, in particular to a bidirectional cutting device for section bars.

Background

The aluminum profile is an aluminum alloy profile, the extrusion molding of the motor shell aluminum profile is completed under the combined action of extrusion force and an extrusion die, and then the motor shell aluminum profile is cut at intervals to form an aluminum motor shell;

because the outer anchor ring equidistance of motor casing aluminium alloy distributes and has more fin, and every fin is thinner, when the cutting, the flexible deformation, among the prior art, carry out the centre gripping to the motor casing aluminium alloy through fixture, the rethread high-speed pivoted cutting piece cuts the motor casing aluminium alloy, easily leads to fin bending deformation, cuts inefficiency. Based on this, also there is corresponding equipment to handle among the prior art, chinese patent (CN 115194872A) discloses a plastic steel section cutting device, the device compresses tightly the upper and lower both sides of section through clamp plate and gyro wheel and fixes, carry out spacing fixed to both sides around the section through chucking mechanism, prevent that the section from taking place to shift when the cutting, the location is accurate, machining precision is high, but because the device is one-way cutting, cutting efficiency is general, and the outer annular surface of motor casing aluminium alloy distributes and has the fin, through the clamp plate of rectangle form, unable adaptation motor casing aluminium alloy's shape stabilizes the centre gripping, if force use the clamp plate to carry out the centre gripping to the motor casing aluminium alloy, lead to the fin to be extruded and warp easily, still can't clear away the inside aluminium bits of motor casing aluminium alloy, lead to in the cutting process, the cutting piece takes the aluminium bits to scrape the cutting plane of flower motor casing aluminium alloy.

Disclosure of Invention

The invention aims to overcome the defects that as a plurality of radiating fins are distributed on the outer ring surface of a motor shell aluminum section at equal intervals, each radiating fin is thin and is easy to bend and deform during cutting, the motor shell aluminum section is clamped by a clamping mechanism and then cut by a cutting blade rotating at a high speed in the prior art, so that the radiating fins are easy to bend and deform, and the cutting efficiency is low, and provide a cutting device which ensures that the radiating fins do not deform and improves the efficiency of cutting the motor shell aluminum section.

Another object of the present invention is to provide a bidirectional cutting device for sectional materials with the above functions.

The embodiment of the invention is realized by the following technical scheme: a two-way cutting device for sectional materials comprises a first rack, a connecting table, a second rack and a conveying system; a connecting table is fixedly connected to the right part of the first frame; the right part of the connecting table is fixedly connected with a second rack; the upper surface of the first frame is connected with a conveying system for conveying the motor shell aluminum profiles; the device also comprises a positioning system, a positioning block, a first scraper, a cutting system and a carrying system; the middle part of the upper surface of the connecting platform is connected with a positioning system for positioning the motor shell aluminum profile; the positioning system is connected with a plurality of positioning blocks for limiting the movement of the cooling fins of the motor shell aluminum profile; the positioning blocks are respectively connected with a first scraper for removing burrs; the front part of the upper surface of the connecting table and the rear part of the upper surface of the connecting table are respectively connected with a cutting system for cutting the motor shell aluminum section, and the two cutting systems are symmetrical in front and back relative to the central axis of the connecting table; the two cutting systems are respectively positioned on the front side and the rear side of the positioning system; the right part of the upper surface of the second rack is connected with a carrying system for carrying motor shell aluminum profiles.

As an improvement of the scheme, the conveying system comprises a first mounting bracket, a first electric push rod, a second mounting bracket, a conveyor, a second electric push rod and a bearing plate; the front part of the upper surface of the first frame and the rear part of the upper surface of the first frame are respectively fixedly connected with a first mounting bracket; the left part of the opposite side and the right part of the opposite side of the two first mounting brackets are fixedly connected with a first electric push rod respectively; a second mounting bracket is fixedly connected with the front two first electric push rod telescopic parts; the two first electric push rod telescopic parts at the rear part are fixedly connected with another second mounting bracket; the two second mounting brackets are symmetrical in the front-back direction relative to the central axis of the first rack; a conveyor is fixedly connected to each of the two second mounting brackets; two second electric push rods are fixedly connected to the middle part of the upper surface of the first frame; two electric putter pars contractilis all the common rigid coupling have the board of accepting.

As an improvement of the above scheme, the positioning system comprises a third mounting bracket, a first annular electric guide rail, a first electric slider, a first limiting block, a first connecting plate, a first sliding column, a first limiting seat, a third electric push rod, a second sliding column, a second limiting seat, a fourth electric push rod and a deburring component; a third mounting bracket is fixedly connected to the middle part of the upper surface of the connecting table; a first annular electric guide rail is fixedly connected to the inner annular surface of the third mounting bracket; the outer surface of the first annular electric guide rail is connected with three first electric sliding blocks in a sliding manner, and the three first electric sliding blocks are distributed in an isosceles triangle shape; each first electric sliding block is fixedly connected with a first limiting block; the upper surface of the third mounting bracket is fixedly connected with a first connecting plate; a second linear sliding groove is formed in the first connecting plate; the first connecting plate is connected with a first sliding column in a sliding mode, and the first sliding column is located in the second linear sliding groove; the lower surface of the first sliding column is fixedly connected with a first limiting seat; a third electric push rod is fixedly connected to the upper part of the right side surface of the third mounting bracket; the telescopic part of the third electric push rod is fixedly connected with the first limiting seat; a first straight line chute is arranged on the connecting platform; the connecting table is connected with a second sliding column in a sliding manner, and the second sliding column is positioned in the first linear sliding groove; the upper surface of the second sliding column is fixedly connected with a second limiting seat; a fourth electric push rod is fixedly connected to the lower part of the right side surface of the third mounting bracket; the telescopic part of the fourth electric push rod is fixedly connected with the second limiting seat; two deburring components are connected to the first limiting seat and the second limiting seat together, and the two deburring components are in bilateral symmetry relative to the central axis of the second limiting seat.

As an improvement of the scheme, the deburring component positioned on the right comprises a circular ring plate, a second limiting block and a spring telescopic column; the first limiting seat and the second limiting seat are rotatably connected with a circular ring plate; three second limiting blocks are fixedly connected to the inner ring surface of the circular ring plate and distributed in an isosceles triangle shape; the isosceles triangles formed by the three second limiting blocks and the isosceles triangles formed by the three first limiting blocks are parallel to each other correspondingly; the inner ring surface of the circular ring plate is fixedly connected with a plurality of positioning blocks; the positioning blocks are arranged in three groups along the annular surface array in the circular annular plate, and the three groups of positioning blocks and the three second limiting blocks are distributed in a staggered manner; each positioning block is fixedly connected with two spring telescopic columns; two spring telescopic columns on each positioning block are fixedly connected with the first scraper.

As an improvement of the scheme, the cutting system comprises a first electric sliding rail, a second electric sliding block, a second connecting plate, a protective cover, a servo motor, a cutting blade, a mounting box and a drawer; two first electric slide rails are fixedly connected to the front part of the upper surface of the connecting table; the outer surfaces of the two first electric sliding rails are respectively connected with a second electric sliding block in a sliding manner; the two second electric sliding blocks are fixedly connected with a second connecting plate together; the upper surface of the second connecting plate is fixedly connected with a protective cover; a servo motor is fixedly connected to the left side surface of the protective cover; the interior of the protective cover is rotationally connected with a cutting blade; the output shaft of the servo motor is fixedly connected with the cutting blade; the lower part of the connecting table is fixedly connected with a mounting box; the mounting box is connected with a drawer in a sliding way; the connecting table is provided with two first guide grooves which are symmetrical front and back relative to the central axis of the connecting table.

As an improvement of the scheme, the carrying system comprises a power assembly, a fourth mounting bracket, a second annular electric guide rail, a fourth electric slide block, a first connecting block, a cylinder, a clamping assembly and a scraping assembly; the second frame is connected with a power assembly; the power assembly is connected with a fourth mounting bracket; a second annular electric guide rail is fixedly connected to the inner annular surface of the fourth mounting bracket; the outer surface of the second annular electric guide rail is connected with three fourth electric sliding blocks in a sliding manner, and the three fourth electric sliding blocks are distributed in an isosceles triangle shape; each fourth electric sliding block is fixedly connected with a first connecting block; the three first connecting blocks are all fixedly connected with a cylinder; a film for anti-collision buffering is adhered to the ring surface of the left wall of the cylinder; the cylinder is connected with three clamping assemblies which are distributed in an annular array; the fourth installing support right flank is connected with scrapes the subassembly to scrape the subassembly and cross the fourth installing support.

As an improvement of the scheme, the clamping assembly comprises a fifth electric push rod, a fourth connecting plate, a slide rod and a pressing plate; a fifth electric push rod is fixedly connected to the cylinder; a fourth connecting plate is fixedly connected with the telescopic part of the fifth electric push rod; two sliding rods are fixedly connected to the fourth connecting plate; the two sliding rods penetrate through the cylinder and are in sliding connection with the cylinder; one end of each sliding rod, which is positioned in the cylinder, is fixedly connected with a pressing plate.

As an improvement of the above scheme, the scraping assembly comprises a fifth mounting bracket, a fixed bracket, a circular tube, a horn tube, a first fixed seat, a fan, a second fixed seat, a sixth electric push rod, a push block, a rotating rod, a second connecting block and a second scraper; a fifth mounting bracket is fixedly connected to the right side surface of the fourth mounting bracket; a fixing support is fixedly connected to the fifth mounting support; a round pipe is fixedly connected to the fixed support; the circular tube is positioned between the pressure plates of the three clamping assemblies; a horn pipe is fixedly connected to the left part of the circular pipe; the outer surface of the circular tube is fixedly connected with three first fixed seats which are distributed in an annular array; the three first fixing seats and the three pressing plates are distributed in a staggered manner; a fan is fixedly connected to each of the three first fixed seats; the upper part and the lower part of the outer surface of the circular tube are fixedly connected with a second fixed seat respectively, and the two second fixed seats are positioned at the left of the three first fixed seats; a sixth electric push rod is fixedly connected to each of the two second fixed seats; the two sixth electric push rod telescopic parts are respectively fixedly connected with a push block, and the two push blocks are vertically symmetrical about the central axis of the horn tube; the upper part and the lower part of the horn pipe are respectively fixedly connected with a rotating rod; the two rotating rods are respectively connected with a second connecting block in a rotating mode, and the two second connecting blocks are symmetrical up and down relative to the central axis of the flared tube; a torsion spring is sleeved on the left part of the outer surface and the right part of the outer surface of each rotating rod respectively; each torsion spring is fixedly connected with the horn pipe and the second connecting block; a second scraper is fixedly connected to each of the two second connecting blocks, and the two second scrapers are vertically symmetrical about the central axis of the flared tube; the two push blocks are respectively contacted with a second connecting block.

As an improvement of the scheme, a second guide groove is formed in the second limiting seat.

Compared with the prior art, the invention has the following advantages:

according to the bidirectional cutting device for the section bar, which is obtained through the design, when the motor shell aluminum section bar moves, all the cooling fins are limited in positioning through the plurality of positioning blocks, so that the problem that the quality of a product is influenced due to bending deformation of the cut parts of all the cooling fins when the cooling fins are cut by the subsequent cutting fins is solved.

According to the bidirectional cutting device for the section bar, which is obtained through the design, before the motor casing aluminum section bar is cut, the three fans blow air into the motor casing aluminum section bar, if aluminum scraps exist on the inner ring surface of the motor casing aluminum section bar, the aluminum scraps can be taken away by leftward air flow, and the phenomenon that when two cutting pieces cut the motor casing aluminum section bar, the two cutting pieces drive the aluminum scraps on the inner ring surface to rotate together is avoided, so that the cutting surface of the motor casing aluminum section bar is scratched.

According to the bidirectional cutting device for the section bar, which is obtained through the design, when the motor shell aluminum section bar is cut, the motor shell aluminum section bar is simultaneously cut from different directions through the two cutting pieces, so that the time for cutting the motor shell aluminum section bar is reduced, and the working efficiency is improved.

According to the bidirectional cutting device for the section bar, which is obtained through the design, in the cutting process of the motor casing aluminum section bar, the aluminum scraps splashed rightwards are blocked through the flared tube, the aluminum scraps splashed on the flared tube are absorbed and removed through the circular tube, then burrs on the inner annular surface of the rotating motor casing aluminum section bar and the inner annular surface of the aluminum motor casing are scraped through the two second scrapers, the problem that a large amount of aluminum scraps are splashed on equipment to cause pollution of the equipment is avoided, and the problem that a subsequent operator carries the aluminum motor casing to scratch the hand is solved.

According to the bidirectional cutting device for the section bar, after the aluminum section bar of the motor shell is cut, burrs on the outer ring surface of the aluminum motor shell are firstly bent and stabbed and broken by the aid of the first scrapers of the right deburring component, the burrs fall onto the second limiting seat, then the two deburring components are driven to move to the right, the burrs on the outer ring surface of the aluminum section bar of the motor shell are bent and stabbed and broken by the first scrapers of the left deburring component, the burrs fall onto the second limiting seat and enter the drawer through the second guide groove and the first guide groove to be collected, accordingly, hand scratching caused by carrying of the aluminum motor shell by a subsequent operator is avoided, and the problem that the device is prone to failure due to more aluminum scrap burrs falling onto the second limiting seat is also avoided.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification.

In the drawings:

fig. 1 is a first perspective view of the bidirectional cutting device for section bar of the present invention;

FIG. 2 is a schematic perspective view of a motor casing aluminum profile of the bidirectional profile cutting device of the present invention;

FIG. 3 is a schematic perspective view of a first frame and a conveying system of the bidirectional cutting device for section bars of the present invention;

fig. 4 is a schematic view of a first three-dimensional structure of a connecting table, a positioning system, a positioning block and a first scraper of the bidirectional cutting device for section bars of the invention;

fig. 5 is a schematic diagram of a second three-dimensional structure of the positioning system, the positioning block and the first scraper of the bidirectional cutting device for section bars according to the present invention;

FIG. 6 is a schematic perspective view of a deburring assembly of the bidirectional cutting device for profiles according to the present invention;

FIG. 7 is a schematic perspective view of the positioning block, the spring telescopic column and the first scraper of the bidirectional cutting device for profiles according to the present invention;

fig. 8 is a schematic perspective view of a connecting table, a second sliding column and a second limiting seat of the bidirectional cutting device for profiles according to the present invention;

fig. 9 is a schematic perspective view of a cutting system of the bidirectional cutting device for profiles according to the present invention;

fig. 10 is a schematic perspective view of a second frame and a carrying system of the bidirectional cutting device for section bars according to the present invention;

FIG. 11 is a partial perspective view of a handling system of the bi-directional cutting device for section bars according to the present invention;

fig. 12 is a partial perspective view of the scraping assembly of the bidirectional cutting device for section bars of the invention.

The reference numbers indicate:

1-a first frame, 2-a connecting table, 3-a second frame, 4-a motor shell aluminum profile,

201-first mounting bracket, 202-first electric push rod, 203-second mounting bracket, 204-conveyor, 205-second electric push rod, 206-adapter plate,

301-a third mounting bracket, 302-a first annular electric guide rail, 303-a first electric slide block, 304-a first limit block, 305-a first connecting plate, 306-a first sliding column, 307-a first limit seat, 308-a third electric push rod, 309-a second sliding column, 310-a second limit seat, 311-a fourth electric push rod, 312-a circular ring plate, 313-a second limit block, 314-a locating block, 315-a spring telescopic column, 316-a first scraper,

401-a first electric slide rail, 402-a second electric slide block, 403-a second connecting plate, 404-a protective cover, 405-a servo motor, 406-a cutting blade, 407-a mounting box, 408-a drawer,

501-a second electric slide rail, 502-a third electric slide block, 503-a third connecting plate, 504-an electric rotary table, 505-a fourth mounting bracket, 506-a second annular electric guide rail, 507-a fourth electric slide block, 508-a first connecting block, 509-a cylinder, 510-a fifth electric push rod, 511-a fourth connecting plate, 512-a slide rod, 513-a press plate, 514-a fifth mounting bracket, 515-a fixed bracket, 516-a circular tube, 517-a horn tube, 518-a first fixed seat, 519-a fan, 520-a second fixed seat, 521-a sixth electric push rod, 522-a push block, 523-a rotary rod, 524-a second connecting block, 525-a second scraper,

2 a-first guide groove, 2 b-first linear sliding groove, 4 a-radiating fin, 4 b-supporting part, 305 a-second linear sliding groove, 310 a-second guide groove and 404 a-barrier strip.

Detailed Description

Embodiments according to the present invention will be described below with reference to the drawings. In the following drawings, the scale of each layer or member is schematically changed as appropriate so that each layer or member can be recognized. It is only noted that the invention is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the invention.

Examples

A two-way cutting device for sectional materials is shown in figures 1-12 and comprises a first machine frame 1, a connecting platform 2, a second machine frame 3 and a conveying system; the right part of the first frame 1 is connected with a connecting platform 2 through a bolt; the right part of the connecting table 2 is connected with a second frame 3 through a bolt; the upper surface of the first frame 1 is connected with a conveying system; the device also comprises a positioning system, a positioning block 314, a first scraper 316, a cutting system and a carrying system; the middle part of the upper surface of the connecting table 2 is connected with a positioning system; the positioning system is connected with a plurality of positioning blocks 314; a first scraper 316 is connected to each of the plurality of positioning blocks 314; the front part of the upper surface and the rear part of the upper surface of the connecting table 2 are respectively connected with a cutting system, and the two cutting systems are symmetrical front and back about the central axis of the connecting table 2; the two cutting systems are respectively positioned on the front side and the rear side of the positioning system; the right part of the upper surface of the second frame 3 is connected with a conveying system.

The conveying system comprises a first mounting bracket 201, a first electric push rod 202, a second mounting bracket 203, a conveyor 204, a second electric push rod 205 and a bearing plate 206; the front part of the upper surface and the rear part of the upper surface of the first frame 1 are respectively connected with a first mounting bracket 201 through bolts; a first electric push rod 202 is fixedly connected to the left part of the opposite side and the right part of the opposite side of each of the two first mounting brackets 201; the front two first electric push rods 202 are fixedly connected with a second mounting bracket 203 at the telescopic part; the telescopic parts of the two rear first electric push rods 202 are fixedly connected with another second mounting bracket 203; the two second mounting brackets 203 are symmetrical in the front-back direction about the central axis of the first frame 1; each bolt on the two second mounting brackets 203 is connected with a conveyor 204; two second electric push rods 205 are fixedly connected to the middle part of the upper surface of the first rack 1; the two telescopic parts of the second electric push rod 205 are both fixedly connected with a bearing plate 206.

The positioning system comprises a third mounting bracket 301, a first annular electric guide rail 302, a first electric slide block 303, a first limit block 304, a first connecting plate 305, a first sliding column 306, a first limit seat 307, a third electric push rod 308, a second sliding column 309, a second limit seat 310, a fourth electric push rod 311 and a deburring component; a third mounting bracket 301 is fixedly connected to the middle part of the upper surface of the connecting table 2; a first annular electric guide rail 302 is connected to the inner annular surface of the third mounting bracket 301 through bolts; the outer surface of the first annular electric guide rail 302 is connected with three first electric sliding blocks 303 in a sliding manner, and the three first electric sliding blocks 303 are distributed in an isosceles triangle shape; each first electric sliding block 303 is fixedly connected with a first limiting block 304; the upper surface of the third mounting bracket 301 is bolted with a first connecting plate 305; the first connecting plate 305 is provided with a second linear chute 305a; a first sliding column 306 is slidably connected to the first connecting plate 305, and the first sliding column 306 is located in the second linear sliding chute 305a; the lower surface of the first sliding pillar 306 is fixedly connected with a first limiting seat 307; a third electric push rod 308 is fixedly connected to the upper part of the right side surface of the third mounting bracket 301; the telescopic part of the third electric push rod 308 is fixedly connected with the first limit seat 307; a first linear chute 2b is arranged on the connecting platform 2; a second sliding column 309 is connected to the connecting table 2 in a sliding manner, and the second sliding column 309 is located in the first linear chute 2b; the upper surface of the second sliding column 309 is fixedly connected with a second limiting seat 310; a fourth electric push rod 311 is fixedly connected to the lower part of the right side surface of the third mounting bracket 301; the telescopic part of the fourth electric push rod 311 is fixedly connected with the second limiting seat 310; the first limiting seat 307 and the second limiting seat 310 are connected with two deburring components together, and the two deburring components are symmetrical left and right about the central axis of the second limiting seat 310.

The deburring component positioned on the right comprises a circular annular plate 312, a second limiting block 313 and a spring telescopic column 315; the first and second limiting

seats

307 and 310 are rotatably connected with a circular ring plate 312; three second limiting blocks 313 are fixedly connected to the inner annular surface of the circular annular plate 312, and the three second limiting blocks 313 are distributed in an isosceles triangle shape; the isosceles triangle formed by the three second limiting blocks 313 is correspondingly parallel to each side of the isosceles triangle formed by the three first limiting blocks 304; the inner ring surface of the circular ring plate 312 is fixedly connected with a plurality of positioning blocks 314; the plurality of positioning blocks 314 are arranged in three groups along the inner annular surface of the circular annular plate 312, and the three groups of positioning blocks 314 and the three second limiting blocks 313 are distributed in a staggered manner; two spring telescopic columns 315 are fixedly connected to each positioning block 314; two spring telescopic columns 315 on each positioning block 314 are fixedly connected with a first scraper 316.

The cutting system comprises a first electric sliding rail 401, a second electric sliding block 402, a second connecting plate 403, a protective cover 404, a servo motor 405, a cutting blade 406, a mounting box 407 and a drawer 408; the front part of the upper surface of the connecting table 2 is connected with two first electric slide rails 401 through bolts; the outer surfaces of the two first electric slide rails 401 are respectively connected with a second electric slide block 402 in a sliding manner; the two second electric sliding blocks 402 are both fixedly connected with a second connecting plate 403; the upper surface of the second connecting plate 403 is connected with a protective cover 404 through bolts; the left side of the protective cover 404 is connected with a servo motor 405 through a bolt; the interior of the protective cover 404 is rotatably connected with a cutting blade 406; the output shaft of the servo motor 405 is fixedly connected with the cutting blade 406; the lower part of the connecting table 2 is fixedly connected with a mounting box 407; the mounting box 407 is slidably connected with a drawer 408; two first guide grooves 2a are formed in the connecting table 2, and the two first guide grooves 2a are symmetrical in the front-back direction with respect to a central axis of the connecting table 2.

The carrying system comprises a power assembly, a fourth mounting bracket 505, a second annular electric guide rail 506, a fourth electric slide block 507, a first connecting block 508, a cylinder 509, a clamping assembly and a scraping assembly; the second frame 3 is connected with a power assembly; a fourth mounting bracket 505 is connected to the power assembly; a second annular electric guide rail 506 is connected to the inner annular surface of the fourth mounting bracket 505 through bolts; the outer surface of the second annular electric guide rail 506 is connected with three fourth electric sliding blocks 507 in a sliding manner, and the three fourth electric sliding blocks 507 are distributed in an isosceles triangle shape; each fourth electric sliding block 507 is fixedly connected with a first connecting block 508; the three first connecting blocks 508 are all fixedly connected with a cylinder 509; a film for collision avoidance and buffering is pasted on the ring surface of the left wall of the cylinder 509; three clamping assemblies are connected to the cylinder 509 and are distributed in an annular array; a scraper assembly is attached to the right side of the fourth mounting bracket 505 and traverses the fourth mounting bracket 505.

The clamping component comprises a fifth electric push rod 510, a fourth connecting plate 511, a sliding rod 512 and a pressing plate 513; a fifth electric push rod 510 is fixedly connected to the cylinder 509; a fourth connecting plate 511 is fixedly connected to the telescopic part of the fifth electric push rod 510; two sliding rods 512 are fixedly connected to the fourth connecting plate 511; two sliding rods 512 pass through the cylinder 509 and are slidably connected with the cylinder 509; a pressing plate 513 is fixed to one end of the two sliding rods 512 inside the cylinder 509.

The scraping component comprises a fifth mounting bracket 514, a fixed bracket 515, a circular tube 516, a flared tube 517, a first fixed seat 518, a fan 519, a second fixed seat 520, a sixth electric push rod 521, a push block 522, a rotating rod 523, a second connecting block 524 and a second scraper 525; the right side of the fourth mounting bracket 505 is connected with a fifth mounting bracket 514 through a bolt; a fixing bracket 515 is fixedly connected to the fifth mounting bracket 514; a round tube 516 is fixedly connected to the fixed support 515; the round tubes 516 are located between the platens 513 of the three clamping assemblies; a horn tube 517 is fixedly connected to the left part of the circular tube 516; three first fixing seats 518 are fixedly connected to the outer surface of the circular tube 516, and the three first fixing seats 518 are distributed in an annular array; the three first fixing seats 518 and the three pressing plates 513 are distributed in a staggered manner; a fan 519 is fixedly connected to each of the three first fixing seats 518; the upper part and the lower part of the outer surface of the circular tube 516 are respectively fixedly connected with a second fixed seat 520, and the two second fixed seats 520 are positioned at the left of the three first fixed seats 518; a sixth electric push rod 521 is fixedly connected to each of the two second fixing seats 520; the two telescopic parts of the sixth electric push rod 521 are respectively fixedly connected with a push block 522, and the two push blocks 522 are vertically symmetrical about the central axis of the horn pipe 517; the upper part and the lower part of the horn pipe 517 are respectively fixedly connected with a rotating rod 523; the two rotating rods 523 are respectively connected with a second connecting block 524 in a rotating manner, and the two second connecting blocks 524 are vertically symmetrical about the central axis of the flared tube 517; a torsion spring is sleeved on the left part of the outer surface and the right part of the outer surface of each rotating rod 523; two ends of each torsion spring are fixedly connected with the horn pipe 517 and the second connecting block 524 respectively; two second connecting blocks 524 are respectively fixedly connected with a second scraper 525, and the two second scrapers 525 are vertically symmetrical about the central axis of the flared tube 517; each of the two push blocks 522 is in contact with one of the second connection blocks 524.

The power assembly comprises a second electric sliding rail 501, a third electric sliding block 502, a third connecting plate 503 and an electric turntable 504; the upper surface of the second frame 3 is connected with two second electric slide rails 501 through bolts; the outer surfaces of the two second electric sliding rails 501 are respectively connected with a third electric sliding block 502 in a sliding manner; the two third electric sliding blocks 502 are fixedly connected with a third connecting plate 503; the upper surface of the third connecting plate 503 is connected with an electric turntable 504 through bolts; the electric turntable 504 is fixedly connected with a fourth mounting bracket 505;

the second stopper seat 310 has a second guiding groove 310a.

Two rows of balls are arranged on each first limiting block 304 and used for assisting the sliding of the motor shell aluminum profiles 4.

Each shield 404 is provided with a barrier 404a, and when aluminum scraps in the shield 404 need to be cleaned, the barrier 404a is manually opened.

As shown in fig. 1-3, the mode of operation of the delivery system:

in the following rotation, the visual angle directions are from front to back, from top to bottom and from right to left; place the two-way cutting device of section bar in the position that needs earlier, and steady subaerial, operating personnel connects the dust shaker on pipe 516, again control two second electric putter 205 and release, the drive is accepted board 206 and is up-moved, place motor casing aluminium alloy 4 on accepting board 206 after that, again control four first electric putter 202 and release, drive second installing support 203 and conveyer 204 and up-move together, let two conveyer 204 and two supporting part 4b contacts of motor casing aluminium alloy 4 lower part, then control two second electric putter 205 contractions, the part that drives and be connected resets, make two conveyer 204 hold motor casing aluminium alloy 4, then control two conveyer 204 and rotate, take motor casing aluminium alloy 4 to turn right the transport.

As shown in fig. 1-2 and 4-8, the positioning system works in the following manner:

when the motor casing aluminum profile 4 moves rightwards, three supporting parts 4b of the motor casing aluminum profile 4 can contact with the balls of the three first limiting blocks 304, the motor casing aluminum profile 4 is positioned through the three first limiting blocks 304, each cooling fin 4a of the motor casing aluminum profile 4 is aligned with a gap between two adjacent positioning blocks 314, each supporting part 4b of the motor casing aluminum profile 4 corresponds to one second limiting block 313, the motor casing aluminum profile 4 is prevented from colliding with the second limiting blocks 313 and the positioning blocks 314 in the rightwards process, the motor casing aluminum profile 4 can smoothly pass through the second limiting blocks 313 and the positioning blocks 314, meanwhile, the balls of the first limiting blocks 304 can assist the motor casing aluminum profile 4 to move rightwards, the friction between the motor casing aluminum profile 4 and the first limiting blocks 304 is reduced, then the three supporting parts 4b of the motor casing aluminum profile 4 contact with the three second limiting blocks 313 of the left deburring component, the motor casing aluminum profile 4 is positioned again through the three second limiting blades 316 which are in the way that the cooling fins contact with the left deburring component and the cooling fins of the motor casing aluminum profile 4, the cooling fins are pushed to move towards the direction of the first limiting blades 316, the cooling fins are pushed by the first limiting blades 316 a, make the outer annular surface contact of the first scraper 316 of a plurality of right-hand deburring subassembly and motor casing aluminium alloy 4, fix a position the restriction to all fin 4a through a plurality of locating piece 314, treat motor casing aluminium alloy 4 and carry to the assigned position after, control two conveyer 204 stall.

As shown in fig. 1-2 and 10-12, the handling system works:

after the motor casing aluminum profile 4 is conveyed to a designated position to the right, the third electric sliding blocks 502 are controlled to move to the left on the outer surface of the second electric sliding rail 501, the two third electric sliding blocks 502 drive the third connecting plate 503, the electric rotating disc 504, the fourth mounting bracket 505, the second annular electric guide rail 506, the fourth electric sliding block 507, the first connecting block 508, the cylinder 509, the clamping component and the scraping component to move to the left together, after a film on the cylinder 509 is contacted with the motor casing aluminum profile 4, the two third electric sliding blocks 502 are controlled to stop moving, at this time, the horn tube 517, the first fixed seat 518, the fan 519, the second fixed seat 520, the sixth electric pushing rod 521, the pushing block 522, the rotating rod 523, the second connecting block 524 and the second scraper 525 are positioned inside the motor casing aluminum profile 4, the three fans 519 are controlled to be started to blow air to the back of the horn tube 517, utilize the direction of horn tube 517, make the air current flow to the left side of pasting motor casing aluminium alloy 4 internal ring face, if follow-up when cutting motor casing aluminium alloy 4, its internal ring face has the aluminium bits, then can be taken away by the air current left, prevent that two cutting pieces 406 are when cutting motor casing aluminium alloy 4, take the aluminium bits of its internal ring face to rotate together, scrape the flower with motor casing aluminium alloy 4's cutting plane, three centre gripping subassembly synchronous operation, use the centre gripping subassembly of top as an example, control fifth electric putter 510 and release, drive fourth connecting plate 511, slide bar 512 and clamp plate 513 move up together, make clamp plate 513 and motor casing aluminium alloy 4 internal ring face contact, two other centre gripping subassemblies also synchronous operation, take two other clamp plates 513 and motor casing aluminium alloy 4 internal ring face contact, carry out the centre gripping through three clamp plate 513 to motor casing aluminium alloy 4 internal ring face.

As shown in fig. 1-2 and 9, the cutting system works in the following manner:

when the three pressing plates 513 clamp the motor casing aluminum profile 4, because the number of the heat radiating fins 4a of the motor casing aluminum profile 4 is large and thin, and the heat radiating fins 4a are easy to bend and deform during cutting, the two cutting systems operate synchronously, taking the cutting system in front as an example, the output shaft of the servo motor 405 is controlled to rotate to drive the cutting blade 406 to rotate, then the second electric slider 402 is controlled to move backwards on the outer surface of the first electric slide rail 401, the two second electric sliders 402 drive the second connecting plate 403, the protective cover 404, the servo motor 405 and the cutting blade 406 to move backwards together, the cutting blade 406 rotating at high speed is used for cutting the motor casing aluminum profile 4, when the cutting blade 406 cuts the heat radiating fins 4a, the positioning blocks 314 of the two deburring components are positioned on the left side and the right side of the moving straight line of the cutting blade 406, the heat radiating fins 4a are positioned and limited by the positioning blocks 314, the cutting blade 406 is prevented from forcing all the heat radiating fins 4a to bend and deform after being cut, the heat radiating fins 406 to affect the quality, the front of the motor casing aluminum profile 4 penetrates through the front part, the front part of the cutting blade 4a, the two cutting systems are controlled to stop the operation of the cutting system, and the cutting system drives the other cutting system to cut the aluminum profile 4a to pass through the aluminum profile 4 in the rear part, and the cutting system.

As shown in fig. 1-2 and 4-8, the positioning system and the handling system work in the following manner:

after the two cutting systems penetrate through the front part and the rear part of the motor casing aluminum profile 4, the four first electric push rods 202 are controlled to contract to drive the connected parts to reset downwards, then the first electric slide block 303 and the fourth electric slide block 507 are controlled to rotate clockwise on the outer surfaces of the first annular electric guide rail 302 and the second annular electric guide rail 506 to drive the first electric slide block 303, the first limiting block 304, the burr removing component, the positioning block 314, the first scraper 316, the fourth electric slide block 507, the first connecting block 508, the cylinder 509, the clamping component and the motor casing aluminum profile 4 to rotate together, the rotating motor casing aluminum profile 4 is continuously cut through the two cutting pieces 406, in the process of cutting the motor casing aluminum profile 4, a large amount of aluminum scraps splash towards the left side and the right side on the inner annular surface of the motor shell aluminum profile 4, the flared tube 517 is positioned on the right side of the two cutting pieces 406, the aluminum scraps splashed towards the right side are blocked, the external dust remover is controlled to be started at the same time, the aluminum scraps splashed on the flared tube 517 are absorbed by the circular tube 516, the phenomenon that a large amount of aluminum scraps splash on equipment to cause pollution is avoided, after the motor shell aluminum profile 4 rotates by one hundred eighty degrees, the two cutting pieces 406 cut off the motor shell aluminum profile 4, the separated motor shell aluminum profile 4 is called an aluminum motor shell for short, the second electric sliding blocks 402 in the two cutting systems are controlled to drive the connected components to reset, and the output shafts of the two servo motors 405 are controlled to stop rotating;

meanwhile, after cutting is finished, because burrs are arranged on the inner ring surfaces and the outer ring surfaces of the motor shell aluminum profile 4 and the aluminum motor shell, when a subsequent operator takes materials, hands are easily scratched, and a potential safety hazard exists, therefore, the two sixth electric push rods 521 are controlled to be pushed out to drive the two push blocks 522 to move left, the two push blocks 522 are used for pushing the two second connecting blocks 524 to respectively rotate in opposite directions with the rotating rod 523 as a circle center, so that the two second connecting blocks 524 respectively drive the second scrapers 525 to rotate in opposite directions, the two second scrapers 525 rotate to simultaneously contact with the inner ring surfaces of the motor shell aluminum profile 4 and the aluminum motor shell, the motor shell aluminum profile 4 and the aluminum motor shell are controlled to stop rotating by the two second scrapers 525 during continuous rotation, after the motor shell aluminum profile 4 and the aluminum motor shell continue to rotate to three hundred sixty degrees, the first electric sliding blocks 303 and the fourth electric sliding blocks 507 are controlled to stop rotating, the inner ring surfaces of the aluminum profile 4 and the aluminum motor shell are scraped by torsion force, the six push rods 521 are controlled to contract, and the two second electric push blocks are automatically reset springs 525 and are connected under the action of the two reset springs 525;

after burrs on the inner ring surface of the aluminum motor shell and the inner ring surface of the aluminum motor shell are scraped, two third electric sliding blocks 502 are controlled to drive connected parts and the aluminum motor shell to move rightwards together, a plurality of first scrapers 316 of the right burr removing assembly cling to the outer ring surface of the aluminum motor shell, burrs on the outer ring surface of the aluminum motor shell are bent, after the aluminum motor shell does not limit the plurality of first scrapers 316 of the right burr removing assembly any more, two spring telescopic columns 315 connected to each first scraper 316 automatically reset, the first scrapers 316 are driven to move downwards, bent burrs on the aluminum motor shell are broken, the broken burrs fall downwards, a second guide groove 310a is formed in the second limiting seat 310, the second guide groove 310a is formed in the second limiting seat, and the second guide groove 2a slides continuously until the broken burrs enter the drawer 408 to be collected;

meanwhile, the third electric push rod 308 and the fourth electric push rod 311 are controlled to be pushed out simultaneously to drive the first sliding column 306, the first limit seat 307, the third electric push rod 308, the second sliding column 309, the second limit seat 310, the fourth electric push rod 311 and the deburring component to move rightwards together, the first sliding column 306 slides in the second linear sliding groove 305a, the second sliding column 309 slides in the first linear sliding groove 2b, the plurality of first scrapers 316 of the left deburring component move rightwards along the outer ring surface of the motor shell aluminum profile 4, burrs on the outer ring surface of the motor shell aluminum profile 4 are bent through the plurality of first scrapers 316, after the plurality of first scrapers 316 are no longer limited by the outer ring surface of the motor shell aluminum profile 4, the two spring telescopic columns 315 connected to each first scraper 316 automatically reset to drive the plurality of first scrapers 316 to move downwards, the bent burrs on the motor shell aluminum profile 4 are poked and broken, so that the second guide grooves 310a poked and the first guide grooves 2a enter the drawer to collect the burrs, the drawer is controlled to control the third electric push rod 308 and the fourth electric push rod 311 to move, and the aluminum profile 311, thereby avoiding the problem that a subsequent aluminum profile conveying person who has more aluminum profile is easy to scratch and cause a failure;

when the two third electric sliding blocks 502 drive the aluminum motor casing to move to the rightmost end continuously, the two third electric sliding blocks 502 are controlled to stop moving, the rotating part of the electric rotating disc 504 is controlled to rotate by one hundred eighty degrees, the fourth mounting bracket 505, the second annular electric guide rail 506, the fourth electric sliding block 507, the first connecting block 508, the cylinder 509, the clamping assembly and the scraping assembly are driven to rotate together, then an operator supports the aluminum motor casing, the three fifth electric push rods 510 are controlled to contract, the connected parts are driven to reset, the aluminum motor casing is not clamped any more, the operator takes the aluminum motor casing away, and then the carrying system is controlled to drive the connected parts to reset.

The embodiments described above are provided to enable persons skilled in the art to make or use the invention and that modifications or variations can be made to the embodiments described above by persons skilled in the art without departing from the inventive concept of the present invention, so that the scope of protection of the present invention is not limited by the embodiments described above but should be accorded the widest scope consistent with the innovative features set forth in the claims.

Claims

1. A two-way cutting device for sectional materials comprises a first machine frame (1), a connecting table (2), a second machine frame (3) and a conveying system; the right part of the first frame (1) is fixedly connected with a connecting table (2); the right part of the connecting table (2) is fixedly connected with a second rack (3); the upper surface of the first frame (1) is connected with a conveying system for conveying the motor shell aluminum profiles (4); the device is characterized by also comprising a positioning system, a positioning block (314), a first scraper (316), a cutting system and a carrying system; the middle part of the upper surface of the connecting table (2) is connected with a positioning system for positioning the motor shell aluminum profile (4); the positioning system is connected with a plurality of positioning blocks (314) for limiting the movement of cooling fins (4 a) of the motor shell aluminum profile (4); a first scraper (316) for removing burrs is connected to each of the positioning blocks (314); the front part of the upper surface and the rear part of the upper surface of the connecting table (2) are respectively connected with a cutting system for cutting the motor shell aluminum profile (4), and the two cutting systems are symmetrical in front and back relative to the central axis of the connecting table (2); the two cutting systems are respectively positioned on the front side and the rear side of the positioning system; the right part of the upper surface of the second rack (3) is connected with a conveying system for conveying the motor shell aluminum profiles (4).

2. A profile bidirectional cutting device according to claim 1, wherein the conveying system comprises a first mounting bracket (201), a first electric push rod (202), a second mounting bracket (203), a conveyor (204), a second electric push rod (205) and a bearing plate (206); the front part of the upper surface and the rear part of the upper surface of the first frame (1) are respectively fixedly connected with a first mounting bracket (201); a first electric push rod (202) is fixedly connected to the left part of the opposite side and the right part of the opposite side of each of the two first mounting brackets (201); a second mounting bracket (203) is fixedly connected with the telescopic parts of the two front first electric push rods (202); the telescopic parts of the two rear first electric push rods (202) are fixedly connected with the other second mounting bracket (203); the two second mounting brackets (203) are symmetrical in the front and back direction relative to the central axis of the first frame (1); a conveyor (204) is fixedly connected to each of the two second mounting brackets (203); two second electric push rods (205) are fixedly connected to the middle part of the upper surface of the first frame (1); the telescopic parts of the two second electric push rods (205) are fixedly connected with a bearing plate (206) together.

3. The two-way cutting device for the section bars, as claimed in claim 2, is characterized in that the positioning system comprises a third mounting bracket (301), a first annular electric guide rail (302), a first electric slide block (303), a first limit block (304), a first connecting plate (305), a first sliding column (306), a first limit seat (307), a third electric push rod (308), a second sliding column (309), a second limit seat (310), a fourth electric push rod (311) and a deburring component; a third mounting bracket (301) is fixedly connected to the middle part of the upper surface of the connecting table (2); a first annular electric guide rail (302) is fixedly connected to the inner annular surface of the third mounting bracket (301); the outer surface of the first annular electric guide rail (302) is connected with three first electric sliding blocks (303) in a sliding manner, and the three first electric sliding blocks (303) are distributed in an isosceles triangle shape; each first electric sliding block (303) is fixedly connected with a first limiting block (304); a first connecting plate (305) is fixedly connected to the upper surface of the third mounting bracket (301); a second straight line chute (305 a) is formed on the first connecting plate (305); a first sliding column (306) is connected to the first connecting plate (305) in a sliding mode, and the first sliding column (306) is located in the second linear sliding groove (305 a); the lower surface of the first sliding column (306) is fixedly connected with a first limit seat (307); a third electric push rod (308) is fixedly connected to the upper part of the right side surface of the third mounting bracket (301); the telescopic part of the third electric push rod (308) is fixedly connected with the first limiting seat (307); a first linear chute (2 b) is arranged on the connecting platform (2); the connecting table (2) is connected with a second sliding column (309) in a sliding mode, and the second sliding column (309) is located in the first linear sliding groove (2 b); the upper surface of the second sliding column (309) is fixedly connected with a second limiting seat (310); a fourth electric push rod (311) is fixedly connected to the lower part of the right side surface of the third mounting bracket (301); the telescopic part of the fourth electric push rod (311) is fixedly connected with the second limiting seat (310); the first limiting seat (307) and the second limiting seat (310) are connected with two deburring components together, and the two deburring components are in bilateral symmetry about a central axis of the second limiting seat (310).

4. A profile bidirectional cutting device according to claim 3, wherein the deburring member at the right side comprises a circular ring plate (312), a second stopper (313) and a spring telescopic column (315); the first limiting seat (307) and the second limiting seat (310) are rotatably connected with a circular ring plate (312); three second limiting blocks (313) are fixedly connected to the inner ring surface of the circular ring plate (312), and the three second limiting blocks (313) are distributed in an isosceles triangle shape; the isosceles triangle formed by the three second limiting blocks (313) is parallel to each side of the isosceles triangle formed by the three first limiting blocks (304); the inner ring surface of the circular ring plate (312) is fixedly connected with a plurality of positioning blocks (314); the positioning blocks (314) are arrayed in three groups along the inner annular surface of the circular annular plate (312), and the three groups of positioning blocks (314) and the three second limiting blocks (313) are distributed in a staggered manner; two spring telescopic columns (315) are fixedly connected to each positioning block (314); two spring telescopic columns (315) on each positioning block (314) are fixedly connected with the first scraper (316).

5. A two-way cutting device for section bars according to claim 4, characterized in that the cutting system comprises a first electric slide rail (401), a second electric slide block (402), a second connecting plate (403), a protective cover (404), a servo motor (405), a cutting blade (406), a mounting box (407) and a drawer (408); two first electric slide rails (401) are fixedly connected to the front part of the upper surface of the connecting table (2); the outer surfaces of the two first electric slide rails (401) are respectively connected with a second electric slide block (402) in a sliding way; the two second electric sliding blocks (402) are jointly and fixedly connected with a second connecting plate (403); a protective cover (404) is fixedly connected to the upper surface of the second connecting plate (403); a servo motor (405) is fixedly connected to the left side surface of the protective cover (404); the interior of the protective cover (404) is rotatably connected with a cutting blade (406); an output shaft of the servo motor (405) is fixedly connected with the cutting blade (406); the lower part of the connecting table (2) is fixedly connected with a mounting box (407); the mounting box (407) is connected with a drawer (408) in a sliding way; two first guide grooves (2 a) are formed in the connecting platform (2), and the two first guide grooves (2 a) are symmetrical in the front-back direction of the central axis of the connecting platform (2).

6. A bidirectional cutting apparatus for profiles according to claim 5, characterized in that the handling system comprises a power assembly, a fourth mounting bracket (505), a second endless electric rail (506), a fourth electric slider (507), a first connecting block (508), a cylinder (509), a holding assembly and a scraping assembly; the second frame (3) is connected with a power assembly; a fourth mounting bracket (505) is connected to the power assembly; a second annular electric guide rail (506) is fixedly connected to the inner ring surface of the fourth mounting bracket (505); the outer surface of the second annular electric guide rail (506) is connected with three fourth electric sliding blocks (507) in a sliding manner, and the three fourth electric sliding blocks (507) are distributed in an isosceles triangle shape; each fourth electric sliding block (507) is fixedly connected with a first connecting block (508); the three first connecting blocks (508) are all fixedly connected with a cylinder (509); a film for anti-collision buffer is pasted on the ring surface of the left wall of the cylinder (509); three clamping assemblies are connected to the cylinder (509) and distributed in an annular array; a scraping assembly is connected to the right side face of the fourth mounting bracket (505) and transversely penetrates through the fourth mounting bracket (505).

7. A bidirectional cutting device for profiles as claimed in claim 6, characterized in that the clamping assembly comprises a fifth electric push rod (510), a fourth connecting plate (511), a slide rod (512) and a pressing plate (513); a fifth electric push rod (510) is fixedly connected to the cylinder (509); a fourth connecting plate (511) is fixedly connected with the telescopic part of the fifth electric push rod (510); two sliding rods (512) are fixedly connected to the fourth connecting plate (511); the two sliding rods (512) penetrate through the cylinder (509) and are connected with the cylinder (509) in a sliding way; one end of each sliding rod (512) positioned in the cylinder (509) is fixedly connected with a pressure plate (513).

8. A two-way cutting device for sectional materials according to claim 7, characterized in that the scraping component comprises a fifth mounting bracket (514), a fixed bracket (515), a round tube (516), a trumpet tube (517), a first fixed seat (518), a fan (519), a second fixed seat (520), a sixth electric push rod (521), a push block (522), a rotating rod (523), a second connecting block (524) and a second scraper (525); a fifth mounting bracket (514) is fixedly connected to the right side surface of the fourth mounting bracket (505); a fixing bracket (515) is fixedly connected to the fifth mounting bracket (514); a round pipe (516) is fixedly connected to the fixed support (515); the round pipe (516) is positioned between the pressure plates (513) of the three clamping assemblies; a horn tube (517) is fixedly connected to the left part of the circular tube (516); three first fixing seats (518) are fixedly connected to the outer surface of the circular tube (516), and the three first fixing seats (518) are distributed in an annular array; the three first fixing seats (518) and the three pressing plates (513) are distributed in a staggered manner; a fan (519) is fixedly connected to each of the three first fixing seats (518); the upper part and the lower part of the outer surface of the circular tube (516) are fixedly connected with a second fixed seat (520) respectively, and the two second fixed seats (520) are positioned at the left of the three first fixed seats (518); a sixth electric push rod (521) is fixedly connected to each of the two second fixed seats (520); the telescopic parts of the two sixth electric push rods (521) are fixedly connected with a push block (522), and the two push blocks (522) are vertically symmetrical about the central axis of the horn tube (517); the upper part and the lower part of the horn pipe (517) are respectively fixedly connected with a rotating rod (523); the two rotating rods (523) are respectively connected with a second connecting block (524) in a rotating mode, and the two second connecting blocks (524) are vertically symmetrical about the central axis of the flared tube (517); a torsion spring is sleeved on the left part of the outer surface and the right part of the outer surface of each rotating rod (523); two ends of each torsion spring are fixedly connected with the horn tube (517) and the second connecting block (524) respectively; a second scraper (525) is fixedly connected to each of the two second connecting blocks (524), and the two second scrapers (525) are vertically symmetrical about the central axis of the flared tube (517); the two pushing blocks (522) are respectively contacted with a second connecting block (524).

9. A profile cutting apparatus in both directions as set forth in claim 3, wherein the second stopper seat (310) is formed with a second guide groove (310 a).