CN114700561A

CN114700561A - Profile processing method and profile processing equipment

Info

Publication number: CN114700561A
Application number: CN202210529847.3A
Authority: CN
Inventors: 夏国章
Original assignee: Foshan Longxin Laser Technology Co ltd
Current assignee: Foshan Longxin Laser Technology Co ltd
Priority date: 2022-05-16
Filing date: 2022-05-16
Publication date: 2022-07-05
Anticipated expiration: 2042-05-16
Also published as: CN114700561B

Abstract

The invention discloses a section processing method and section processing equipment, wherein the section processing method comprises the following steps: s1, conveying the section to a material supporting part by a conveying assembly; s2, a material supporting wheel of the material supporting part supports the section, the height of the material supporting wheel is adjusted until the center of the section on the material supporting part is matched with the height of a chuck, and the chuck moves towards one side close to the section and then clamps the end part of the section; s3, cutting the clamped section by the machining assembly, driving the section to rotate by the chuck, synchronously rotating the material supporting wheel, and discharging after cutting; s4, repeating the steps S1-S3 until the machining of the profile is completed. The conveying assembly and the feeding assembly directly feed the heavy pipe or the large pipe, so that the feeding efficiency is higher. When the chuck drives the section bar to rotate, the material supporting wheel and the section bar rotate synchronously, namely, the material supporting wheel always supports the section bar in the cutting process and does not separate from the section bar, so that the deformation of the section bar in the cutting process is avoided, and the cutting precision is improved.

Description

Profile processing method and profile processing equipment

Technical Field

The invention relates to the technical field of profile processing methods, in particular to a profile processing method and profile processing equipment.

Background

In the field of building construction, profile processing equipment such as cutting equipment occupies a larger part of mechanical equipment, and compared with the traditional manual processing, the manual processing consumes longer time when the profile with harder material is processed; by adopting mechanical processing, more time and labor cost can be saved, the processing surface is smoother, and the quality of the processed product is better. Therefore, the profile processing equipment is widely used in various large factories and construction sites.

The existing section bar processing equipment is mainly used for processing slender section bars, for example, a feeding frame is used for feeding, two groups of chucks or three groups of chucks are used for fixing the section bars together, and a cutting head is used for cutting the section bars; and then adopt the mode of artifical transport to heavy pipe or the great big pipe of diameter to carry out the material loading, efficiency is lower, and the section bar leads to scraping the flower because of colliding with easily in handling during the material loading.

Disclosure of Invention

The invention aims to provide a profile processing method and profile processing equipment, and aims to solve the technical problems that in the prior art, no profile processing equipment for heavy pipes or large pipes exists, the processing efficiency is low, and the profiles are easy to scratch.

In order to achieve the purpose, the invention provides a profile processing method, which comprises the following steps:

s1, conveying the section to a material supporting part by a conveying assembly;

s2, a material supporting wheel of the material supporting part supports the section, the height of the material supporting wheel is adjusted until the center of the section on the material supporting part is matched with the height of a chuck, and the chuck moves towards one side close to the section and then clamps the end part of the section;

s3, cutting the clamped section by the machining assembly, driving the section to rotate by the chuck, synchronously rotating the material supporting wheel, and discharging after cutting;

s4, repeating the steps S1-S3 until the machining of the profile is completed.

The automatic feeding of the section bar is realized by adopting the conveying assembly, and the feeding efficiency is improved. And be provided with the material supporting wheel in this scheme and be used for supporting the section bar, drive its rotation after the chuck presss from both sides tight section bar, the material supporting wheel can rotate along with the rotation synchronization of section bar, and the material supporting wheel holds the section bar bottom completely at the cutting in-process promptly, does not break away from with the section bar, has played better supporting effect, has avoided the deformation of section bar cutting process.

Preferably, before the step of clamping the end of the profile after the chuck moves to one side close to the profile, the pushing assembly pushes the profile on the material supporting wheel to one side close to the chuck until the chuck can clamp the end of the profile.

After the section bar is conveyed to the material supporting wheel by the conveying assembly, the clamping head is close to the section bar and clamps the section bar. Because the section bar is conveyed to the material supporting wheel and can randomly move to any position, and the distance between some positions and the chuck is far, the section bar pushing assembly is arranged in the scheme and used for further pushing the section bar, so that the section bar is close to the chuck, and the chuck is convenient for clamping the section bar.

Preferably, when the processing assembly cuts the section bar, the deslagging assembly extends into the section bar to collect scraps generated during cutting. The sweeps that produce when the slagging-off subassembly is collected and is cut the section bar avoids the sweeps to pile up inside the section bar, and follow-up still needs to add a clean process, has improved machining efficiency.

In addition, the invention also provides a section processing device, which uses the section processing method, and comprises the following steps: the conveying assembly is used for conveying the section to the material supporting part;

the processing table is positioned behind the conveying assembly, a material supporting part for supporting the sectional material is arranged on the processing table, and an adjusting assembly for adjusting the height of the material supporting part is arranged below the material supporting part so as to ensure that the center of the sectional material on the material supporting part is matched with the height of the chuck;

the clamping head is movably arranged on one side of the material supporting part and is used for clamping the section on the material supporting part;

and the processing assembly is movably arranged on the processing table and is used for cutting the clamped section.

The height of the material supporting part can be adjusted to adapt to the section bars with different sizes, so that the clamping head can better clamp the end parts of the section bars; and the material supporting wheel follows up when the chuck drives the section bar to rotate, thereby playing a better supporting role for the section bar.

Preferably, the material supporting part comprises an installation plate and material supporting wheels, the installation plate is arranged on the processing table in a lifting manner, the two groups of material supporting wheels are rotatably arranged on a roll shaft of the installation plate, a material supporting gap is formed between the two groups of material supporting wheels, and the width W of the material supporting gap is less than or equal to the diameter D1 of the section;

the mounting plate is provided with a material pushing assembly, the material pushing assembly comprises a first telescopic piece and a material pushing part, the first telescopic piece is positioned on the other side of the material supporting part, and the output end of the first telescopic piece is fixed with the material pushing part, so that the first telescopic piece can drive the material pushing part to move along the axial direction of the section bar when being stretched, and the section bar is pushed until the section bar is close to the chuck;

the adjusting component comprises a first hand wheel, a first transmission rod, a spiral lifter and a lifting rod, wherein the first hand wheel is installed on the processing table, the first hand wheel is connected with the spiral lifter, the spiral lifter is located below the mounting plate, the lifting rod is movably arranged below the mounting plate, the first hand wheel can be driven to rotate, the spiral lifter and the lifting rod synchronously lift, and therefore the mounting plate and the section bar on the supporting wheel lift.

The material is supported between the material supporting gaps of the two rows of material supporting wheels, the rotating directions of the material supporting wheels and the chucks are kept consistent, and the section is always supported in the cutting process. In addition, one side of the mounting plate is provided with a material pushing assembly, the material pushing assembly can push the section bar to be close to the chuck, and the chuck is convenient to clamp the section bar in the subsequent process. The height of the material supporting wheel on the processing table can be adjusted, and the height of the material supporting part is correspondingly adjusted according to the profiles with different sizes due to the change of the diameters of the profiles, so that the center of the profile is matched with the height of the chuck, and the chuck is convenient to clamp the profile.

Preferably, the processing table is provided with a first guide rail extending along the axial direction of the section bar, the first guide rail is provided with a first movable sliding block, the chuck is fixed with the first sliding block, and the chuck is connected with the output end of the second telescopic piece, so that the second telescopic piece can drive the chuck and the first sliding block to move on the first guide rail when being telescopic.

The second telescopic piece drives the chuck to move along the first guide rail so as to be close to or far away from the section bar, the end part of the section bar is clamped when the section bar is close to the section bar, so that the cutting assembly can be conveniently cut, and the section bar is loosened when the section bar is far away from the section bar to finish blanking.

Preferably, the material loading device further comprises a material loading assembly, wherein the material loading assembly comprises a material rack, a first driver, a first connecting rod and a material ejecting part, a first feeding section and a second feeding section which incline downwards are arranged on the material rack, the height of the top end of the second feeding section is greater than that of the first feeding section, the output end of the first driver is fixed with the first connecting rod, two ends of the first connecting rod are connected with the material ejecting part, the material rack is provided with a first sliding chute, the first connecting rod can move up and down in the first sliding chute, on a side projection plane, an overlapping area exists between the material ejecting part and the first material loading section, and an overlapping area exists between the second material loading section and the conveying assembly, so that when the first driver drives the first connecting rod and the material ejecting part to lift, the profile can be jacked up and transported to a second loading section, after which the profile continues to be transported to the conveyor assembly;

the feeding assembly further comprises a second hand wheel, a second transmission rod, a second connecting rod and an adjusting piece, the second hand wheel passes through the second transmission rod and is connected with the second connecting rod, a second chute is formed in the material rack, the second connecting rod can move horizontally in the second chute, two ends of the second connecting rod are fixed to the adjusting piece, the adjusting piece is close to one end of the second feeding section and extends upwards to form a material blocking portion, the adjusting piece is partially overlapped with the material ejecting piece on a side projection surface, and therefore the second hand wheel can be rotated to drive the second connecting rod to move horizontally in the second chute, so that the adjusting piece can be adjusted with the overlapping length of the material ejecting piece.

The feeding assembly is located in front of the conveying assembly and used for controlling the feeding quantity of a batch of sectional materials, when the first driver drives the material ejecting part to ascend, partial sectional materials in the sectional materials on the material rack can be ejected, one or two sectional materials can be in actual production, the partial sectional materials are firstly conveyed to the second feeding section, and then the sectional materials are conveyed to the conveying assembly through the inclined second feeding section. This scheme is in order to adapt to not unidimensional section bar, has add the adjusting part, when rotating the second hand wheel, can change the overlapping length between adjusting part and the liftout piece, because the end of adjusting part is equipped with and keeps off material portion, keeps off the regional liftout piece that material portion the place ahead and liftout piece overlapped promptly and be the region that can jack-up section bar, section bar outside this region can drop when liftout piece rises, not in same batch material loading.

Preferably, the material conveying device further comprises an auxiliary assembly, the auxiliary assembly comprises guide plates and linkage rods, one end of each guide plate is rotatably connected with the corresponding roller shaft, the guide plates are distributed in an array mode and connected through the linkage rods, an overlapping area exists between each guide plate and the tail end of the conveying assembly on a side projection surface, the height of the tail end of the conveying assembly is larger than or equal to that of the material supporting wheel, and therefore the section materials are conveyed to the guide plates through the conveying assembly and then conveyed to the material supporting wheel through the guide plates.

Because certain interval has between conveyor components's end and the support material wheel, for the convenience of the transport of section bar, be provided with the deflector and be convenient for the continuation transport of section bar, when the section bar was carried to conveyor components end, will fall on the deflector, the deflector downward sloping usually, the section bar continues to move along the deflector of slope, has realized the material loading process promptly until falling between two rows of support material wheels.

Preferably, conveying component's head end with the terminal rotatable coupling of work or material rest, conveying component's below is equipped with angle adjusting component, angle adjusting component includes third hand wheel, third transfer line and second spiral riser, the third hand wheel passes through the third transfer line with the second spiral riser is connected, the upper end of second spiral riser with conveying component is fixed, makes to rotate the third hand wheel can drive the lift of second spiral riser, thereby the adjustment conveying component's inclination.

Because the processing platform height of difference differs, in order to adapt to the processing platform of co-altitude not, be convenient for transport the section bar to the material wheel from conveyor components, this scheme has set up angle adjusting part in the conveyor components below, and when rotating the third hand wheel, the second spiral elevator rises or descends, leads to conveyor components's inclination grow or diminish, until with the better correspondence of processing bench material wheel ability.

Preferably, the slag removing device further comprises a slag removing component, wherein the slag removing component comprises a slag suction pipe, a second driver, a synchronous belt, a fixed plate and a mounting rack, a second guide rail extending along the axial direction of the sectional material is arranged on the mounting rack, a second slide block is movably mounted on the second guide rail, the fixed plate is fixed with the second slide block, the slag suction pipe is mounted on the fixed plate and communicated with a suction device, the output end of the second driver is fixed with the synchronous belt, and the synchronous belt is fixed with the fixed plate, so that when the second driver drives the synchronous belt to rotate, the fixed plate and the slag suction pipe can be driven to move on the second guide rail;

the diameter D2 of the slag suction pipe is smaller than the diameter D1 of the section bar, and a material receiving part is sleeved at one end of the slag suction pipe, which extends into the section bar;

still be equipped with vertical extension's third guide rail on the mounting bracket, third slider mobilizable installation is in on the third guide rail, the fourth hand wheel is connected with the connecting rod, the mobilizable passing of connecting rod third guide rail with the third slider is fixed, the fixed plate with the third slider is fixed, makes to rotate during the fourth hand wheel, drive the third slider the fixed plate is in with the scum pipe elevating movement on the third guide rail.

The section processing method and the section processing equipment have the following beneficial effects: the conveying assembly and the feeding assembly directly feed the heavy pipe or the large pipe, so that the feeding efficiency is higher. When the chuck drives the section bar to rotate, the material supporting wheel and the section bar synchronously rotate, namely, the material supporting wheel always supports the section bar in the cutting process and does not separate from the section bar, so that the deformation of the section bar in the cutting process is avoided, and the cutting precision is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural view of the profile processing apparatus of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is an enlarged view of a portion of FIG. 1 at B;

FIG. 4 is an enlarged view of a portion of FIG. 1 at C;

FIG. 5 is a schematic view of another angle structure of the apparatus for processing a section bar according to the present invention;

FIG. 6 is an enlarged view of a portion of FIG. 5 at D;

FIG. 7 is a schematic side-projection structure of the apparatus for processing a profile according to the present invention;

FIG. 8 is a schematic view of the auxiliary assembly and the material supporting wheel of the profile processing apparatus of the present invention;

fig. 9 is a schematic side view of the profile working apparatus of the present invention with the conveyor assembly and the loading assembly removed.

In the drawings: 1-conveying component, 11-angle adjusting component, 111-third hand wheel, 112-third transmission rod, 113-second spiral lifter, 2-processing table, 21-material supporting part, 211-mounting plate, 212-material supporting wheel, 213-material supporting gap, 22-first guide rail, 23-first sliding block, 24-second telescopic component, 3-adjusting component, 31-first hand wheel, 32-first transmission rod, 33-first spiral lifter, 34-lifting rod, 4-chuck, 5-processing component, 6-feeding component, 61-material rack, 611-first feeding segment, 612-second feeding segment, 613-first sliding slot, 614-second sliding slot, 62-first driver, 63-first connecting rod, 64-material pushing part, 65-second hand wheel, 66-second transmission rod, 67-second connecting rod, 68-adjusting part, 681-material blocking part, 7-deslagging component, 71-slag suction pipe, 711-material receiving part, 72-second driver, 73-synchronous belt, 74-fixing plate, 75-mounting frame, 751-second guide rail, 752-second slide block, 753-third guide rail, 754-third slide block, 755-fourth hand wheel, 756-connecting rod, 8-section bar, 9-material pushing component, 91-first telescopic part, 92-material pushing part, 10-auxiliary component, 101-guide plate and 102-linkage rod.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that if directional indications such as up, down, left, right, front, and rear … … are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship, motion, and the like between the components in a specific posture as shown in the drawings, and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description of "first", "second", etc. in an embodiment of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

As shown in fig. 1 to 9, a profile processing method includes the steps of:

s1, conveying the section bar 8 to a material supporting part 21 by a conveying assembly 1;

s2, supporting the section bar 8 by the material supporting wheel 212 of the material supporting part 21, adjusting the height of the material supporting wheel 212 until the center of the section bar 8 on the material supporting part 21 is matched with the height of the chuck 4, and clamping the end part of the section bar 8 after the chuck 4 moves to one side close to the section bar 8;

s3, cutting the clamped section bar 8 by the machining assembly 5, driving the section bar 8 to rotate by the chuck 4, synchronously rotating the material supporting wheel 212, and blanking after cutting;

s4, repeating the steps S1-S3 until the machining of the section bar 8 is completed.

In the embodiment, the section processing method is mainly suitable for processing various sections 8 such as steel pipes and the like, is particularly suitable for processing heavy pipes or sections 8 with large sizes, has high feeding efficiency, can better avoid the deformation of the sections 8 in the cutting process, and has high cutting precision.

Specifically, in the scheme, the section 8 rolls off on the material rack 61 and then is conveyed to the conveying assembly 1, the section 8 is directly fed by the conveying assembly 1, the feeding efficiency is high in a mechanical feeding mode, the section 8 is conveyed to the material supporting part 21 through the conveying assembly 1 and is supported by the material supporting wheel 212 of the material supporting part 21, the position of the material supporting wheel 212 after installation can ensure that a plane formed by a central line of the section 8 supported by the section 8 and a central line of the chuck 4 is vertical to a horizontal plane, before the cutting of the processing assembly 5, the height of the material supporting part 21 (the material supporting wheel 212) is adjusted, so that the central height of the section 8 is consistent with the central height of the chuck 4, and the chuck 4 can smoothly clamp the end part of the section 8; heavy pipe or big pipe dead weight are heavier and the volume is great, it is comparatively inconvenient to remove, chuck 4 in this scheme is close to with pressing from both sides tight section bar 8 to section bar 8, press from both sides tight back with section bar 8 when chuck 4, processing subassembly 5 cuts section bar 8, processing subassembly 5 need not rotate around section bar 8, drive section bar 8 by chuck 4 and rotate the operation such as cutting off with completion section bar 8, current support material wheel 212 only carries out the bearing to section bar 8 when material loading or unloading, can't carry out the bearing to section bar 8 during the cutting, and heavy pipe or big pipe are not bearing easy deformation in the cutting process, therefore, the support material wheel 212 of this scheme rotates with section bar 8 synchronous when chuck 4 drives section bar 8 and rotates, the cutting process supports section bar 8 completely promptly, section bar 8 deformation has been avoided, the cutting precision has been improved. After the cutting is completed, the profile 8 is blanked by means of existing blanking equipment or directly by hand.

Further, before the step of clamping the end of the profile 8 after the collet 4 moves to the side close to the profile 8, the pushing assembly 9 pushes the profile 8 on the material supporting wheel 212 to the side close to the collet 4 until the collet 4 can clamp the end of the profile 8.

Except that the chuck 4 can move towards the end part of the section bar 8, the scheme is additionally provided with the material pushing assembly 9, so that the situation that the section bar 8 rolled to the material supporting wheel 212 is too far away from the chuck 4 to cause that the section bar 8 cannot be clamped after the chuck 4 approaches is prevented, and the material pushing assembly 9 can push the section bar 8 to one side close to the chuck 4, so that the chuck 4 does not need to move too much.

Further, in step S3, when the processing assembly 5 cuts the profile 8, the deslagging assembly 7 extends into the profile 8 to collect the scraps generated during cutting. The scrap in the section bar 8 is absorbed in real time when the slag removing component 7 is used for cutting, the scrap is prevented from being gathered in the section bar 8, a cleaning process is required to be added subsequently, and the processing efficiency is further improved.

In addition, the invention also provides a section processing device, and the section processing method comprises the following steps: a conveying assembly 1 for conveying the profile 8 to the material supporting portion 21;

the processing table 2 is positioned behind the conveying assembly 1, a material supporting part 21 for supporting the section bar 8 is arranged on the processing table 2, an adjusting assembly 3 for adjusting the height of the material supporting part 21 is arranged below the material supporting part 21 so as to ensure that the center of the section bar 8 on the material supporting part 21 is matched with the height of the chuck 4, the material supporting part 21 comprises an installation plate 211 and material supporting wheels 212, the installation plate 211 is arranged on the processing table 2 in a lifting manner, the two groups of material supporting wheels 212 are rotatably arranged on a roller shaft of the installation plate 211, a material supporting gap 213 is formed between the two groups of material supporting wheels 212, and the width W of the material supporting gap 213 is less than or equal to the diameter D1 of the section bar 8;

the clamping head 4 is movably arranged on one side of the material supporting part 21, and the clamping head 4 is used for clamping the section bar 8 on the material supporting part 21;

and the processing assembly 5 is movably arranged on the processing table 2, and the processing assembly 5 is used for cutting the clamped section bar 8.

The conveying assembly 1 conveys the section 8 to the material supporting part 21 on the processing table 2, and the section 8 is supported by the material supporting wheel 212 of the material supporting part 21, and then the adjusting assembly 3 is lifted or lowered to keep the center of the section 8 on the material supporting wheel 212 and the center of the chuck 4 at the same horizontal height, so that the subsequent chuck 4 can conveniently clamp the end part of the section 8; after chuck 4 presss from both sides tight section bar 8, processing subassembly 5 cuts section bar 8, chuck 4 constantly drives section bar 8 rotatory during the cutting, make the different faces of section bar 8 all can be cut by processing subassembly 5, when section bar 8 rotates, the material wheel 212 of holding in the palm of bottom follows its synchronous rotation, consequently, do not take place to break away from between material wheel 212 and the section bar 8, material wheel 212 supports section bar 8 at the cutting in-process always, can not take place easily deformation to heavier heavy pipe or big pipe, better cutting accuracy has been guaranteed. In actual production, two sets (rows) of material supporting wheels 212 respectively located at two sides of the profile 8, each set of material supporting wheels 212 can be continuously multiple, for example, the material supporting wheels 212 at two sides of the profile 8 can be composed of 5 material supporting wheels 212, so as to support the profile 8 with a long length, in other embodiments, the number of the material supporting wheels 212 in each row can be adaptively changed, for example, 3 or 6 material supporting wheels are formed to form a row of material supporting wheels 212.

The processing assembly 5 in the scheme is composed of a three-axis moving assembly (capable of freely moving in an X axis, a Y axis or a Z axis) and a laser cutting head, and can cut or cut off the pattern of the section bar 8. Conveying component 1 can be chain formula conveyer belt or belt conveyor etc. and the interval is provided with and carries out spacing fender material post to section bar 8 on chain formula conveyer belt, prevents that a plurality of section bars 8 on conveying component 1 from rolling the back and bumping, leads to the damaged deformation of section bar 8. In specific production, the outer covers can be arranged outside the processing assembly 5 and the processing table 2, so that a better protection effect is achieved.

The mounting plate 211 is provided with a material pushing assembly 9, the material pushing assembly 9 comprises a first telescopic piece 91 and a material pushing portion 92, the first telescopic piece 91 is located on the other side of the material supporting portion 21, and the output end of the first telescopic piece 91 is fixed with the material pushing portion 92, so that the first telescopic piece 91 can drive the material pushing portion 92 to move along the axial direction of the section bar 8 when being telescopic, and the section bar 8 is pushed until being close to the chuck 4;

adjusting part 3 includes first hand wheel 31, first transfer line 32, spiral riser and lifter 34, first hand wheel 31 is installed processing platform 2 is last, and it passes through first transfer line 32 with spiral riser connects, spiral riser is located the mounting panel 211 below, the mobilizable setting of lifter 34 the mounting panel 211 below for rotate first hand wheel 31 can drive spiral riser and lifter 34 are synchronous, thereby realize the mounting panel 211 with the section bar 8 on the material supporting wheel 212 goes up and down.

It can be understood that, because the profile 8 may be located at any position when being conveyed to the material supporting wheel 212, when the distance between the profile 8 and the chuck 4 is too far, the chuck 4 cannot clamp the end of the profile 8 after moving, at this time, the material pushing assembly 9 pushes the profile 8 toward the chuck 4, the first telescopic member 91 extends out to make the material pushing portion 92 contact with the profile 8, and continues to extend out to make the profile 8 move toward the direction close to the chuck 4 until the chuck 4 can conveniently clamp the profile 8, when in actual production, the material pushing assembly 9 may be used to push the profile 8, or the chuck 4 may be used to be close to the profile 8, and the selection is adapted to different use scenarios.

The adjusting assembly 3 is used for adjusting the heights of the mounting plate 211 and the material supporting wheel 212, so that the central heights of the profiles 8 with different sizes can be consistent with the central height of the chuck 4. After rotating first hand wheel 31, the spiral lifter can rise or descend to drive mounting panel 211 to rise or descend, four edges of mounting panel 211 all are equipped with the lifter 34 of liftable, and lifter 34 follows up when the spiral lifter drives mounting panel 211 and goes up and down, plays the guide effect. In other embodiments, an air cylinder or the like may be used to drive the mounting plate 211 to move up and down.

Furthermore, a first guide rail 22 extending along the axial direction of the section bar 8 is arranged on the processing table 2, a movable first sliding block 23 is arranged on the first guide rail 22, the chuck 4 is fixed with the first sliding block 23, and the chuck 4 is connected with the output end of a second telescopic part 24, so that the chuck 4 and the first sliding block 23 can be driven to move on the first guide rail 22 when the second telescopic part 24 is stretched.

In the scheme, the direction of the first guide rail 22 is consistent with the axial direction of the section bar 8, so that the chuck 4 is close to the end part of the section bar 8 when moving, the second telescopic part 24 is fixed on the processing table 2 through a mounting seat, the output end of the second telescopic part 24 is fixed with the chuck 4, and when the second telescopic part 24 extends out, the chuck 4 and the first sliding block 23 can be driven to move along the first guide rail 22, specifically, the direction close to the section bar 8, so as to clamp the end part of the section bar 8; when the second telescopic element 24 is retracted, the collet 4 and the first slide 23 move in opposite directions along the first guide 22, away from the profile 8, to effect blanking. The first and

second telescoping members

91, 24 may be pneumatic cylinders or the like.

Further, the feeding assembly 6 is further included, the feeding assembly 6 includes a material rack 61, a first driver 62, a first connecting rod 63 and a material ejecting part 64, the material rack 61 is provided with a first material loading section 611 and a second material loading section 612 which are inclined downwards, the height of the top end of the second material loading section 612 is greater than the height of the first material loading section 611, the output end of the first driver 62 is fixed with the first connecting rod 63, both ends of the first connecting rod 63 are connected with the material ejecting part 64, the material rack 61 is provided with a first sliding chute 613, the first connecting rod 63 can move up and down on the first sliding chute 613, on a side projection plane, an overlapping area exists between the material ejecting part 64 and the first material loading section 611, and an overlapping area exists between the second material loading section 612 and the conveying assembly 1, so that when the first driver 62 drives the first connecting rod 63 and the material ejecting part 64 to lift up, the profile 8 can be lifted and transported to the second loading section 612, after which the profile 8 continues to be transported to the conveyor assembly 1.

The material frame 61 is provided with a first material loading section 611 and a second material loading section 612 which are inclined, the second material loading section 612 is located behind the first material loading section 611, the height of the second material loading section 612 is high, a plurality of sectional materials 8 can be placed on the first material loading section 611, and the plurality of sectional materials 8 can be blocked by the second material loading section 612. When loading is needed, the first driver 62 is started, the first driver 62 drives the first connecting rod 63 and the material ejecting member 64 to rise until the first connecting rod 63 is flush with the second loading section 612 or slightly higher than the second loading section 612, the material ejecting member 64 is specifically positioned at the top end of the first connecting rod 63, the upper surface can be arranged in a horizontal or inclined form, the upper surface inclined ejector 64 facilitates the rolling (forward transport) of the profile 8, the profile 8 continues to roll along the inclined ejector 64 to the second loading section 612, after which the profile 8 continues to roll via the inclined second loading section 612 to the conveyor assembly 1, since there is only a partial overlap area between the ejector 64 and the first unloading section, that is, not all the profiles 8 on the first feeding segment 611 can be jacked up by the jacking members 64, only part of the profiles 8 in the overlapping area will be jacked up, and the overlapping area of the two is usually set to jack up only one profile 8 in a specific production. Of course, in other embodiments, if two profiles 8 need to be jacked up, it may be implemented that the size of the overlapping area of the two profiles is correspondingly adjusted. The first actuator 62 may also be an air cylinder or the like.

The feeding assembly 6 further comprises a second hand wheel 65, a second transmission rod 66, a second connecting rod 67 and an adjusting piece 68, the second hand wheel 65 is connected with the second connecting rod 67 through a second transmission rod 66, a second chute 614 is arranged on the material frame 61, the second connecting rod 67 can horizontally move in the second chute 614, two ends of the second connecting rod 67 are fixed to the adjusting piece 68, the adjusting piece 68 is close to one end of the second feeding section 612 and upwards extends to form a material blocking portion 681, and on a side projection plane, the adjusting piece 68 is partially overlapped with the material ejecting piece 64, so that when the second hand wheel 65 is rotated, the second connecting rod 67 is driven to horizontally move in the second chute 614 to adjust the overlapping length of the adjusting piece 68 and the material ejecting piece 64.

In order to better change the size of the overlapped area of the first feeding section 611 and the ejecting member 64, the adjustment can be performed by the second hand wheel 65, when the second hand wheel 65 is rotated, the adjusting member 68 horizontally moves in the second sliding groove 614 and drives the adjusting member 68 to be close to or far away from the end of the first feeding section 611, because the tail end of the adjusting member 68 is provided with the stopping portion 681, when the adjusting member 68 is arranged, the section bar 8 on the first feeding section 611 is not stopped by the head end of the second feeding section 612, but is stopped by the stopping portion 681, when the second hand wheel 65 drives the adjusting member 68 to be close to the tail end of the first feeding section 611, the overlapped area of the first feeding section 611 and the ejecting member 64 is enlarged, otherwise, the overlapped area of the first feeding section 611 and the ejecting member 64 is reduced, so that the overlapping area of the first feeding section bar 611 and the ejecting member 64 can be better adapted to the ejecting process of the section bars 8 with different sizes, and the application range is wider.

Further, the auxiliary assembly 10 is further included, the auxiliary assembly 10 includes guide plates 101 and linkage rods 102, one ends of the guide plates 101 are rotatably connected with the roller shafts, a plurality of guide plates 101 are distributed in an array mode, the guide plates 101 are connected through the linkage rods 102, on a side projection plane, an overlapping area exists between the guide plates 101 and the tail end of the conveying assembly 1, and the height of the tail end of the conveying assembly 1 is larger than or equal to that of the material supporting wheel 212, so that the section bar 8 is conveyed to the guide plates 101 through the conveying assembly 1 and then conveyed to the material supporting wheel 212 through the guide plates 101.

In order to prevent the end of the conveying assembly 1 from interfering with the cutting assembly, a certain distance is usually provided between the end of the conveying assembly 1 and the retainer plate, an auxiliary assembly 10 is provided for assisting in better transportation of the profile 8, wherein the profile 8 is received by the guide plate 101 when transported to the end of the conveying assembly 1, generally, the end of the conveying assembly 1 is slightly higher than the retainer wheel 212, that is, the guide plate 101 is inclined at a certain angle, and the profile 8 is continuously transported to between the two rows of retainer wheels 212 along the inclined guide plate 101, so that the loading process of the profile 8 is realized. In this scheme, the one end of deflector 101 is dead with the roller card when carrying out section bar 8 auxiliary transportation, when conveying assembly 1's inclination changes, rotation that deflector 101 also can correspond is until the terminal better correspondence with conveying assembly 1, later die the one end card of roller and deflector 101 again, deflector 101 specifically is provided with a plurality ofly, and a plurality of deflector 101 interval arrays, can play better bearing effect to heavy pipe/big pipe, keep the state after the rotation unanimous through gangbar 102 between a plurality of deflectors 101.

Further, the below of conveying component 1 is equipped with angle adjusting component 11, angle adjusting component 11 includes third hand wheel 111, third transfer line 112 and second spiral riser 113, third hand wheel 111 passes through third transfer line 112 with second spiral riser 113 is connected, second spiral riser 113's upper end with conveying component 1 is fixed, makes to rotate third hand wheel 111 can drive second spiral riser 113 goes up and down, thereby adjusts conveying component 1's inclination.

Because the heights of different processing stations 2 are different, in order to better adapt to various different processing stations 2, an angle adjusting component 11 is arranged below the conveying component 1, so that the inclination angle of the conveying component 1 is increased or decreased, and the conveying component can be better matched with the processing stations 2 with different heights. When the third hand wheel 111 in the angle adjusting assembly 11 is rotated, the spiral lifter synchronously ascends or descends, the conveying assembly 1 synchronously ascends during ascending, the inclination angle is increased, and the device is suitable for a processing table 2 with a higher height, and conversely, the device is suitable for a processing table 2 with a lower height. In other embodiments, an air cylinder may be used to drive the conveying assembly 1 to rotate (ascend) instead of the screw lifter.

Further, the slag removing device comprises a slag removing assembly 7, wherein the slag removing assembly 7 comprises a slag suction pipe 71, a second driver 72, a synchronous belt 73, a fixed plate 74 and a mounting rack 75, a second guide rail 751 extending along the axial direction of the profile 8 is arranged on the mounting rack 75, a second slider 752 is movably mounted on the second guide rail 751, the fixed plate 74 and the second slider 752 are fixed, the slag suction pipe 71 is mounted on the fixed plate 74, the slag suction pipe 71 is communicated with a suction device (not shown in the figure), the output end of the second driver 72 is fixed with the synchronous belt 73, and the synchronous belt 73 is fixed with the fixed plate 74, so that when the second driver 72 drives the synchronous belt 73 to rotate, the fixed plate 74 and the slag suction pipe 71 can be driven to move on the second guide rail 751;

the diameter D2 of the slag suction pipe 71 is smaller than the diameter D1 of the section bar 8, and a material receiving part 711 is sleeved at one end, extending into the section bar 8, of the slag suction pipe 71;

the mounting frame 75 is further provided with a third guide rail 753 extending vertically, a third sliding block 754 is movably mounted on the third guide rail 753, a fourth hand wheel 755 is connected with a connecting rod 756, the connecting rod 756 can movably penetrate through the third guide rail 753 to be fixed with the third sliding block 754, and the fixing plate 74 is fixed with the third sliding block 754, so that when the fourth hand wheel 755 is rotated, the third sliding block 754, the fixing plate 74 and the slag suction pipe 71 are driven to move up and down on the third guide rail 753.

The slag suction pipe 71 of the slag removal component 7 can suck the waste chips when the processing component 5 cuts the section bar 8, prevents the waste chips from gathering inside the section bar 8 after being cut, and because the slag suction pipe 71 is communicated with the suction device, most of the waste chips can be sucked away through the suction force of the suction device. In order to adapt to the movement of the section bar 8, the deslagging assembly 7 can also move freely, under the drive of the second driver 72 and the synchronous belt 73, the slag suction pipe 71 and the fixed plate 74 can move along the second guide rail 751, and because the second guide rail 751 and the axial direction of the section bar 8 are on the same straight line, the slag suction pipe 71 can be close to or far away from the section bar 8 when moving, during slag suction operation, the slag suction pipe 71 usually extends into the section bar 8, waste scraps are sucked in the section bar 8, in order to better collect the waste scraps, the scheme is that the tail end of the slag suction pipe 71 is provided with a material receiving part 711, the opening of the material receiving part 711 faces upwards, during cutting, the tail end of the slag suction pipe 71 is close to a cutting point, therefore, the material receiving part 711 can receive most of the cutting waste scraps, and a better slag suction effect is achieved; in addition, the slag suction pipe 71 can move up and down through the fourth hand wheel 755 so as to adapt to the profiles 8 with different sizes, and when the fourth hand wheel 755 is rotated, the third sliding block 754 is driven to move along the third guide rail 753, so that the slag suction pipe 71 can move up and down.

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

Claims

1. A profile machining method is characterized by comprising the following steps:

s1, conveying the section bar (8) to a material supporting part (21) by a conveying assembly (1);

s2, supporting the section (8) by a material supporting wheel (212) of the material supporting part (21), adjusting the height of the material supporting wheel (212) until the center of the section (8) on the material supporting part (21) is matched with the height of a chuck (4), and clamping the end part of the section (8) after the chuck (4) moves to one side close to the section (8);

s3, cutting the clamped section (8) by the machining assembly (5), driving the section (8) to rotate by the chuck (4), synchronously rotating the material supporting wheel (212), and blanking after cutting;

s4, repeating the steps S1-S3 until the machining of the profile (8) is completed.

2. A profile working method according to claim 1, characterized in that before the step of clamping the end of the profile (8) after the collet (4) has moved to the side near the profile (8), the pushing assembly (9) pushes the profile (8) on the wheel (212) to the side near the collet (4) until the collet (4) can grip the end of the profile (8).

3. The method of claim 1, wherein in step S3, when the processing assembly (5) cuts the profile (8), the deslagging assembly (7) extends into the profile (8) to collect the scraps generated during cutting.

4. A profile working apparatus, characterized by using the profile working method according to any one of claims 1 to 3, comprising:

a conveying assembly (1) for conveying the profile (8) to the material-holding portion (21);

the processing table (2) is located behind the conveying assembly (1), a material supporting portion (21) used for supporting the sectional material (8) is arranged on the processing table (2), an adjusting assembly (3) used for adjusting the height of the material supporting portion (21) is arranged below the material supporting portion (21) to ensure that the center of the sectional material (8) on the material supporting portion (21) is matched with the height of the chuck (4), the material supporting portion (21) comprises an installation plate (211) and material supporting wheels (212), the installation plate (211) is arranged on the processing table (2) in a lifting mode, the two groups of material supporting wheels (212) are rotatably arranged on a roll shaft of the installation plate (211), a material supporting gap (213) is formed between the two groups of material supporting wheels (212), and the width W of the material supporting gap (213) is not more than the diameter D1 of the sectional material (8);

the clamping head (4) is movably arranged on one side of the material supporting part (21), and the clamping head (4) is used for clamping the section (8) on the material supporting part (21);

and the machining assembly (5) is movably arranged on the machining table (2), and the machining assembly (5) is used for cutting the clamped section (8).

5. The profile machining equipment according to claim 4, wherein a material pushing assembly (9) is arranged on the mounting plate (211), the material pushing assembly (9) comprises a first telescopic piece (91) and a material pushing portion (92), the first telescopic piece (91) is located on the other side of the material supporting portion (21), and an output end of the first telescopic piece is fixed to the material pushing portion (92), so that the first telescopic piece (91) can drive the material pushing portion (92) to move axially along the profile (8) when being stretched, and the profile (8) is pushed to be close to the chuck (4);

adjusting part (3) include first hand wheel (31), first transfer line (32), first spiral lift (33) and lifter (34), first hand wheel (31) are installed processing platform (2) are last, and it passes through first transfer line (32) with first spiral lift (33) are connected, first spiral lift (33) are located mounting panel (211) below, lifter (34) mobilizable setting mounting panel (211) below for rotate first hand wheel (31) can drive first spiral lift (33) and lifter (34) synchronous lift, thereby realize mounting panel (211) with section bar (8) on holding in the palm material wheel (212) go up and down.

6. A profile machining apparatus according to claim 4, characterized in that the machining table (2) is provided with a first guide rail (22) extending in the axial direction of the profile (8), the first guide rail (22) is provided with a first movable slide (23), the collet (4) is fixed to the first slide (23), and the collet (4) is connected to the output of a second telescopic part (24) such that the second telescopic part (24) can move the collet (4) and the first slide (23) along the first guide rail (22) when it is extended or retracted.

7. A profile processing apparatus according to claim 4, further comprising a feeding assembly (6), wherein the feeding assembly (6) comprises a material frame (61), a first driver (62), a first connecting rod (63) and a material ejecting member (64), the material frame (61) is provided with a first feeding section (611) and a second feeding section (612) which are inclined downwards, the top end of the second feeding section (612) has a height larger than the height of the first feeding section (611), the output end of the first driver (62) is fixed with the first connecting rod (63), the two ends of the first connecting rod (63) are connected with the material ejecting member (64), the material frame (61) is provided with a first sliding chute (613), the first connecting rod (63) can move up and down in the first sliding chute (613), and on the side projection plane, the material ejecting member (64) and the first feeding section (611) have an overlapping region, the second feeding section (612) is positioned behind the material jacking part (64), and the second feeding section (612) and the conveying assembly (1) have an overlapping area, so that when the first driver (62) drives the first connecting rod (63) and the material jacking part (64) to lift up, the section bar (8) can be jacked up and conveyed to the second feeding section (612), and then the section bar (8) is conveyed to the conveying assembly (1) continuously;

the feeding assembly (6) further comprises a second hand wheel (65), a second transmission rod (66), a second connecting rod (67) and an adjusting piece (68), the second hand wheel (65) is connected with the second connecting rod (67) through the second transmission rod (66), a second sliding groove (614) is formed in the material frame (61), the second connecting rod (67) can horizontally move in the second sliding groove (614), two ends of the second connecting rod (67) are fixed with the adjusting piece (68), one end, close to the second feeding section (612), of the adjusting piece (68) extends upwards to form a material blocking part (681), on a side projection surface, the adjusting piece (68) is partially overlapped with the material pushing piece (64) so that when the second hand wheel (65) is rotated, the second connecting rod (67) is driven to horizontally move in the second sliding groove (614), so as to adjust the overlapping length of the adjusting piece (68) and the jacking piece (64).

8. The profile machining equipment according to claim 5, further comprising an auxiliary assembly (10), wherein the auxiliary assembly (10) comprises guide plates (101) and a linkage rod (102), one end of each guide plate (101) is rotatably connected with the corresponding roller shaft, a plurality of guide plates (101) are distributed in an array mode, the guide plates (101) are connected through the linkage rod (102), an overlapping area exists between each guide plate (101) and the tail end of the conveying assembly (1) on a side projection plane, the height of the tail end of the conveying assembly (1) is larger than or equal to that of the material supporting wheel (212), and therefore the profile (8) is conveyed to the guide plates (101) through the conveying assembly (1) and then conveyed to the material supporting wheel (212) through the guide plates (101).

9. The profile machining equipment according to claim 7, characterized in that the head end of the conveying assembly (1) is rotatably connected with the tail end of the material rack (61), an angle adjusting assembly (11) is arranged below the conveying assembly (1), the angle adjusting assembly (11) comprises a third hand wheel (111), a third transmission rod (112) and a second spiral lifter (113), the third hand wheel (111) is connected with the second spiral lifter (113) through the third transmission rod (112), the upper end of the second spiral lifter (113) is fixed to the conveying assembly (1), and the third hand wheel (111) is rotated to drive the second spiral lifter (113) to ascend and descend so as to adjust the inclination angle of the conveying assembly (1).

10. The profile processing device according to claim 4, further comprising a deslagging assembly (7), wherein the deslagging assembly (7) comprises a deslagging pipe (71), a second driver (72), a synchronous belt (73), a fixed plate (74) and a mounting bracket (75), a second guide rail (751) extending along the axial direction of the profile (8) is arranged on the mounting bracket (75), a second slider (752) is movably mounted on the second guide rail (751), the fixed plate (74) is fixed to the second slider (752), the deslagging pipe (71) is mounted on the fixed plate (74), the deslagging pipe (71) is communicated with a suction device, an output end of the second driver (72) is fixed to the synchronous belt (73), the synchronous belt (73) is fixed to the fixed plate (74), so that the second driver (72) drives the synchronous belt (73) to rotate, the fixing plate (74) and the slag suction pipe (71) can be driven to move on the second guide rail (751);

the diameter D2 of the slag suction pipe (71) is less than the diameter D1 of the section bar (8), and a material receiving part (711) is sleeved at one end of the slag suction pipe (71) extending into the section bar (8);

the mounting rack (75) is further provided with a third guide rail (753) extending vertically, a third sliding block (754) is movably mounted on the third guide rail (753), a fourth hand wheel (755) is connected with a connecting rod (756), the connecting rod (756) movably penetrates through the third guide rail (753) and is fixed with the third sliding block (754), and the fixing plate (74) is fixed with the third sliding block (754) so that when the fourth hand wheel (755) is rotated, the third sliding block (754), the fixing plate (74) and the slag suction pipe (71) are driven to ascend and descend on the third guide rail (753).