CN219881990U - Profile cutting processing production line - Google Patents

Abstract

The utility model discloses a section bar cutting processing production line, which relates to the technical field of section bar automatic processing devices, and comprises the following steps: the cutting mechanism is used for cutting the section bar, and the opposite sides of the cutting mechanism are respectively provided with a feeding end and a discharging end; the conveying and positioning mechanism is used for conveying and positioning the section bar and is positioned at one side of the feeding end; the clamping and feeding mechanism is arranged at the tail end of the conveying and positioning mechanism and clamps the profile from the conveying and positioning mechanism to the cutting mechanism; the processing mechanisms are used for processing the sectional materials and are arranged at one side of the discharging end at intervals; and the transfer robot moves through the ground rail so as to transfer the profile of the discharge end to any processing mechanism. The profile cutting and processing production line realizes automatic feeding and processing, reduces labor intensity, improves production efficiency and improves processing precision.

Description

Profile cutting processing production line

Technical Field

The utility model relates to the technical field of automatic section bar processing devices, in particular to a section bar cutting processing production line.

Background

The section bar refers to a solid straight bar with a certain section shape and size, which is formed by plastic processing of metal. After the profile is formed, the profile is subjected to cutting, milling, drilling and other procedures to obtain the specification and the size required by manufacturing and installation.

At present, the cutting procedure and the processing procedure of the section bar are all completed manually, the section bar is cut into the required length by a cutting machine, the section bar is transported to a processing station for milling procedure or drilling procedure after the cutting is completed, and the processing procedure is also completed manually. The manual operation has the problems of high labor intensity, low efficiency and low machining precision.

Disclosure of Invention

The utility model mainly aims to provide a profile cutting and processing production line, and aims to provide a profile cutting and processing production line which realizes automatic feeding and processing, reduces labor intensity, improves production efficiency and improves processing precision.

In order to achieve the above object, the present utility model provides a profile cutting and processing line for automatic processing of profiles, the profile cutting and processing line comprising:

the cutting mechanism is used for cutting the section bar, and the opposite sides of the cutting mechanism are respectively provided with a feeding end and a discharging end;

the conveying and positioning mechanism is used for conveying and positioning the section bar and is positioned at one side of the feeding end;

the clamping and feeding mechanism is arranged at the tail end of the conveying and positioning mechanism and clamps the profile from the conveying and positioning mechanism to the cutting mechanism;

the processing mechanisms are used for processing the sectional materials and are arranged at one side of the discharging end at intervals;

and the transfer robot moves through the ground rail so as to transfer the profile of the discharge end to any processing mechanism.

Optionally, the cutting mechanism includes:

the workbench is provided with an installation cavity and a cutting groove communicated with the installation cavity, and the cutting groove is positioned between the feeding end and the discharging end;

the cutting machine is provided with a saw blade and is slidably arranged in the mounting cavity, so that the saw blade extends out of or retracts into the cutting groove;

the upper pressing component is used for pressing the top of the section bar and is arranged on the workbench;

the side compression assembly is used for compressing the side face of the section bar and is arranged on the workbench.

Optionally, the side press assembly is slidably engaged with the table to effect movement between the cutting slot and the discharge end.

Optionally, the side compression assembly includes:

the sliding seat is in sliding fit with the workbench;

the sliding cylinder is arranged on the workbench;

the driving plate is arranged on the sliding seat and is connected with a piston rod of the sliding cylinder;

the first compression cylinder is arranged on the sliding seat;

the first compacting plate is arranged on a piston rod of the first compacting cylinder.

Optionally, the upper compression assembly includes:

the supporting seat is arranged on the workbench;

the second pressing cylinder is arranged on the supporting seat;

the second compacting plate is arranged on a piston rod of the second compacting cylinder.

Optionally, the conveying and positioning mechanism includes:

the first support frame is provided with a plurality of belt conveying assemblies at intervals;

the second support frame is arranged at intervals in front and back of the first support frame, the output end of the belt conveying assembly is positioned above the second support frame, and the clamping feeding mechanism is in sliding fit with the second support frame;

the positioning assemblies are arranged in a plurality and spaced mode on the second supporting frame.

Optionally, the positioning assembly comprises a first blocking assembly and a second blocking assembly, and the profile is limited between the first blocking assembly and the second blocking assembly;

the first fender material subassembly includes:

the first connecting plate is arranged on the second supporting frame;

the first lifting cylinder is arranged on the first connecting plate;

the roller seat is positioned above the first connecting plate and is connected with a piston rod of the first lifting cylinder;

the first material blocking column is abutted with the front side of the section bar and is arranged on the roller seat;

the second keeps off material subassembly includes:

the second connecting plate is arranged on the second supporting frame;

the horizontal driving cylinder is arranged on the second connecting plate;

the adjusting seat is in sliding fit with the second connecting plate and is connected with a piston rod of the horizontal driving cylinder;

the second lifting cylinder is arranged on the adjusting seat;

and the second material blocking column is in butt joint with the rear side of the section bar and is connected with a piston rod of the second lifting cylinder.

Optionally, realize sliding fit through rack and pinion drive between clamping feeding mechanism and the second support frame, clamping feeding mechanism includes:

the mounting seat is in sliding fit with the second supporting frame and is provided with a lower supporting plate;

the third compression cylinder is arranged at the top of the mounting seat;

the third compacting plate is connected with a piston rod of the third compacting cylinder, and the third compacting cylinder drives the third compacting plate to be close to or far away from the lower supporting plate.

Optionally, the profile cutting production line further comprises a scrap trailer, wherein the scrap trailer is located on one side of the second support frame away from the cutting mechanism.

Optionally, the processing mechanism has a positioning jig assembly for profile fixation, the positioning jig assembly comprising:

the movable base is driven by the power device to move on a horizontal plane;

the rotating seat is arranged on the movable base and is provided with a rotating connecting plate driven by a numerical control dividing plate to realize rotation;

the clamping seat is driven by the air cylinder to realize clamping, and the clamping seat is detachably arranged on the rotating connecting plate.

The technical scheme of the utility model comprises a cutting mechanism, a conveying and positioning mechanism, a clamping and feeding mechanism, a processing mechanism and a carrying robot, wherein the clamping and feeding mechanism clamps the section bar conveyed to the tail end of the conveying and positioning mechanism to the position of the cutting mechanism for cutting, and the section bar after cutting is clamped to any processing mechanism by the carrying robot for processing the section bar. Due to the adoption of the technical means of automatic conveying, automatic feeding, automatic cutting and automatic machining of the sectional materials, the technical problems of high labor intensity, low efficiency and low machining precision in manual operation in the prior art are effectively solved, and the technical effects of reducing the labor intensity, improving the production efficiency and improving the machining precision are further realized.

Drawings

FIG. 1 is a schematic view of a section bar cutting line according to an embodiment of the present utility model;

FIG. 2 is a schematic top view of the profile cutting line of the present utility model;

FIG. 3 is a schematic view of a cutting mechanism according to an embodiment of the present utility model;

FIG. 4 is a schematic view of a cutting mechanism according to another embodiment of the present utility model;

FIG. 5 is a schematic view of the internal structure of the cutting mechanism of the present utility model;

FIG. 6 is a schematic view of the upper compression assembly of the present utility model;

FIG. 7 is a schematic view of a side compression assembly according to the present utility model;

FIG. 8 is a schematic view of a transport positioning mechanism according to the present utility model;

FIG. 9 is a schematic view of a transport positioning mechanism according to another embodiment of the present utility model;

FIG. 10 is a schematic view of a first material blocking assembly according to the present utility model;

FIG. 11 is a schematic view of a second material blocking assembly according to the present utility model;

FIG. 12 is a schematic view of a clamping and feeding mechanism according to the present utility model;

FIG. 13 is a schematic view of a clamping feed mechanism according to another embodiment of the present utility model;

FIG. 14 is a schematic view of a processing mechanism according to the present utility model;

FIG. 15 is a schematic view of a positioning fixture assembly of the present utility model;

reference numerals illustrate:

a profile cutting processing line 100; a cutting mechanism 10; a work table 11; cutting grooves 111; a cutter 12; an upper press assembly 13; a support base 131; a second pressing cylinder 132; a second pressing plate 133; a side hold down assembly 14; a sliding seat 141; a slide cylinder 142; a driving plate 143; a first compaction cylinder 144; a first pressing plate 145; a conveyance positioning mechanism 20; a first support frame 21; a belt conveyor assembly 211; a second support 22; a positioning assembly 23; a first stop assembly 231; first connection plate 2311; a first lifting cylinder 2312; roller seat 2313; first dam post 2314; a second stop assembly 232; a second connection plate 2321; a horizontal driving cylinder 2322; an adjustment seat 2323; a second lifting cylinder 2324; a second dam 2325; a clamp feeding mechanism 30; a mounting base 31; a lower support plate 311; a third pressing cylinder 32; a third pressing plate 33; a pushing cylinder 34; a pusher plate 35; a processing mechanism 40; a positioning jig assembly 41; a moving base 411; a rotating base 412; a numerical control index plate 413; a milling cutter assembly 42; a transfer robot 50; a ground rail 60; and a waste trailer 70.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

In the present utility model, unless specifically stated and limited otherwise, the terms "connected," "affixed," and the like are to be construed broadly, and for example, "affixed" may be a fixed connection, a removable connection, or an integral body; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

Furthermore, descriptions such as those referred to as "first," "second," and the like, are provided for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implying an order of magnitude of the indicated technical features in the present disclosure. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

The utility model provides a profile cutting processing production line 100 which is used for automatic processing of profiles, replaces manual operation and improves production efficiency and processing precision.

In order to better understand the above technical solutions, the following detailed description will refer to the accompanying drawings and specific embodiments.

In the embodiment of the present utility model, as shown in fig. 1 and 2, the profile cutting and processing production line 100 includes a cutting mechanism 10, a conveying and positioning mechanism 20, a clamping and feeding mechanism 30, a processing mechanism 40 and a carrying robot 50, wherein the cutting mechanism 10 is used for cutting a profile, and two opposite sides of the cutting mechanism 10 are respectively a feeding end and a discharging end; the conveying and positioning mechanism 20 is used for conveying and positioning the section bar, and the conveying and positioning mechanism 20 is positioned at one side of the feeding end; the clamping and feeding mechanism 30 is arranged at the tail end of the conveying and positioning mechanism 20 and clamps the profile from the conveying and positioning mechanism 20 to the cutting mechanism 10; the processing mechanism 40 is used for processing the profile, and a plurality of processing mechanisms 40 are arranged at intervals on one side of the discharging end; the transfer robot 50 moves by the ground rail 60 to transfer the profile at the discharge end to any one of the processing mechanisms 40.

It will be appreciated that the cutting mechanism 10 is used for cutting the profile to a required length, the conveying and positioning mechanism 20 is used for conveying and positioning the profile, the front end of the conveying and positioning mechanism 20 is a profile feeding end, the tail end is a profile discharging end, one side close to the profile feeding end is a raw material storage area for storing the profile to be cut, staff carries the profile to be cut to the profile feeding end position of the conveying and positioning mechanism 20, the conveying and positioning mechanism 20 conveys the profile to the direction of the profile discharging end, a clamping and feeding mechanism 30 is arranged at the profile discharging end position, the profile is clamped to the cutting mechanism 10 from the conveying and positioning mechanism 20, the profile extends from the feeding end side of the cutting mechanism 10, the cut profile is positioned at the discharging end side of the cutting mechanism 10, the movement of the clamping and feeding mechanism 30 is the feeding of the profile, the specific distance can be moved according to the required cutting length, the cut profile is carried to the processing mechanism 40 by the carrying robot 50 to realize the next processing procedure, the processing procedure includes but not limited to milling processing and drilling processing, because the time required by the cutting procedure is far less than the time required by the processing procedure, the utility model sets a plurality of processing mechanisms 40, so that the front and back procedures are more reasonable, the station waiting time is reduced, the carrying robot 50 realizes the movement through the ground rail 60, the carrying robot 50 and the ground rail 60 are provided with a guide rail sliding block structure, and the movement is realized through a gear rack transmission mechanism, the utility model is also provided with a plurality of finished product trays for placing the profile which completes the processing procedure, the finished product trays have a plurality of and respectively correspond to the plurality of processing mechanisms 40, the carrying robot 50 is responsible for carrying the cut profile to the position of the processing mechanism 40 to carry out the processing procedure, and the section bar after the processing procedure is carried to the position of the finished product tray to realize blanking.

The technical scheme of the utility model comprises a cutting mechanism 10, a conveying and positioning mechanism 20, a clamping and feeding mechanism 30, a processing mechanism 40 and a carrying robot 50, wherein the clamping and feeding mechanism 30 clamps the section bar conveyed to the tail end of the conveying and positioning mechanism 20 to the position of the cutting mechanism 10 for cutting, and the carrier robot 50 clamps the cut section bar to any processing mechanism 40 for processing the section bar. Due to the adoption of the technical means of automatic conveying, automatic feeding, automatic cutting and automatic machining of the sectional materials, the technical problems of high labor intensity, low efficiency and low machining precision in manual operation in the prior art are effectively solved, and the technical effects of reducing the labor intensity, improving the production efficiency and improving the machining precision are further realized.

In the embodiment of the present utility model, as shown in fig. 3, 4 and 5, the cutting mechanism 10 includes a table 11, a cutter 12, an upper pressing assembly 13 and a side pressing assembly 14, wherein the table 11 is provided with a mounting chamber and a cutting groove 111 communicating with the mounting chamber, the cutting groove 111 being located between a feed end and a discharge end; the cutter 12 has a saw blade, and the cutter 12 is slidably provided in the mounting chamber so that the saw blade is extended or retracted into the cutting slot 111; the upper pressing component 13 is used for pressing the top of the section bar, and the upper pressing component 13 is arranged on the workbench 11; the side compression assembly 14 is used for compressing the side surface of the profile, and the side compression assembly 14 is arranged on the workbench 11.

It will be appreciated that the profile is fed from the feed end side, when the profile is delivered to a designated position, the upper pressing assembly 13 and the side pressing assembly 14 respectively act to press and fix the profile, then the cutter 12 slides, so that the saw blade extends out of the cutting slot 111 and cuts the profile, after the cutting is completed, the cutter 12 slides, so that the saw blade retracts into the installation cavity, and the upper pressing assembly 13 and the side pressing assembly 14 release the profile, the profile on the discharge end side is clamped to any processing mechanism 40 by the transfer robot 50, and the profile on the feed end side is fed by the clamping feeding mechanism 30 to perform the next profile cutting process. In the present utility model, the cutter 12 is slid by the cylinder drive, the saw blade is extended from the position of the cutting groove 111 and profile cutting is achieved when the piston rod of the cylinder is extended, and the saw blade is retracted from the position of the cutting groove 111 to the inside of the installation cavity when the piston rod of the cylinder is retracted, and in addition, the saw blade is rotated by the drive motor and the timing belt.

In an embodiment of the present utility model, as shown in fig. 3, 4 and 5, the side press assembly 14 is slidably engaged with the table 11 to effect movement between the cutting slot 111 and the discharge end. The side pressing assembly 14 plays a supporting role on the profile, and after cutting is completed, the side pressing assembly 14 carries the profile to slide to the discharging end side, so that the carrying robot 50 can conveniently clamp the profile.

In the embodiment of the present utility model, as shown in fig. 7, the side compression assembly 14 includes a slide seat 141, a slide cylinder 142, a driving plate 143, a first compression cylinder 144, and a first compression plate 145, wherein the slide seat 141 is slidably engaged with the table 11; the sliding cylinder 142 is arranged on the workbench 11; the driving plate 143 is arranged on the sliding seat 141 and is connected with a piston rod of the sliding cylinder 142; the first compression cylinder 144 is arranged on the sliding seat 141; the first pressing plate 145 is provided to a piston rod of the first pressing cylinder 144. The sliding seat 141 is L type, including mutually perpendicular's first board and second board, first board passes through guide rail slider structure with workstation 11 and realizes sliding fit, drive plate 143 is connected with first board, the second board is used for bearing the section bar, when carrying out the section bar cutting, sliding cylinder 142 drive sliding seat 141 removes to the position that is close to cutting groove 111, the second board plays the supporting role to the section bar, simultaneously, first clamp cylinder 144 drive first clamp plate 145 is towards being close to the direction removal of first board for the section bar is held between first clamp plate 145 and first board, after accomplishing the cutting, sliding cylinder 142 drive sliding seat 141 is moved towards the direction of discharge end, first clamp cylinder 144 unclamp the section bar, in order to make things convenient for transfer robot 50 to carry out the centre gripping.

In the embodiment of the present utility model, as shown in fig. 6, the upper compressing assembly 13 includes a supporting base 131, a second compressing cylinder 132, and a second compressing plate 133, wherein the supporting base 131 is provided at the table 11; the second compression cylinder 132 is arranged on the supporting seat 131; the second pressing plate 133 is disposed on a piston rod of the second pressing cylinder 132. When the profile needs to be compressed, the second compressing cylinder 132 drives the second compressing plate 133 to move towards the direction close to the second plate, and when the profile needs to be loosened, the second compressing cylinder 132 drives the second compressing plate 133 to move towards the direction far away from the second plate.

In the embodiment of the present utility model, as shown in fig. 8 and 9, the conveying and positioning mechanism 20 includes a first support frame 21, a second support frame 22 and a positioning assembly 23, wherein the first support frame 21 is provided with a plurality of spaced belt conveying assemblies 211; the second support frame 22 and the first support frame 21 are arranged at intervals in the front-back direction, the output end of the belt conveying assembly 211 is positioned above the second support frame 22, and the clamping and feeding mechanism 30 is in sliding fit with the second support frame 22; the positioning components 23 are plural and are disposed at intervals on the second supporting frame 22. When the profile is fed to the output end of the belt conveyor assembly 211, positioning is achieved by the positioning assembly 23 to facilitate clamping of the profile by the clamping feed mechanism 30.

In the embodiment of the utility model, as shown in fig. 8, 9, 10 and 11, the positioning assembly 23 comprises a first material blocking assembly 231 and a second material blocking assembly 232, and the profile is limited between the first material blocking assembly 231 and the second material blocking assembly 232; specifically, the first material blocking component 231 includes a first connection plate 2311, a first lifting cylinder 2312, a roller seat 2313 and a first material blocking column 2314, where the first connection plate 2311 is disposed on the second support frame 22; the first lifting cylinder 2312 is disposed on the first connection plate 2311; the roller seat 2313 is located above the first connecting plate 2311 and connected with a piston rod of the first lifting cylinder 2312; the first material blocking post 2314 is abutted with the front side of the section bar, and the first material blocking post 2314 is arranged on the roller seat 2313; the second material blocking assembly 232 comprises a second connecting plate 2321, a horizontal driving cylinder 2322, an adjusting seat 2323, a second lifting cylinder 2324 and a second material blocking column 2325, wherein the second connecting plate 2321 is arranged on the second supporting frame 22; the horizontal driving cylinder 2322 is arranged on the second connecting plate 2321; the adjusting seat 2323 is in sliding fit with the second connecting plate 2321 and is connected with a piston rod of the horizontal driving cylinder 2322; the second lifting cylinder 2324 is arranged on the adjusting seat 2323; the second material blocking column 2325 is abutted with the rear side of the section bar, and the second material blocking column 2325 is connected with a piston rod of the second lifting cylinder 2324.

It will be appreciated that when the profile is being transported, the first stop post 2314 and the second stop post 2325 are moved downward by the driving of the lifting cylinder to a height lower than the height of the belt transporting assembly 211, when the belt transporting assembly 211 transports the profile to the end position, the first lifting cylinder 2312 drives the roller seat 2313 and the first stop post 2314 to move upward, the roller on the roller seat 2313 lifts the profile upward, so that the profile is separated from the belt transporting assembly 211, meanwhile, the first stop post 2314 limits the front side of the new cover, then the second lifting cylinder 2324 drives the second stop post 2325 to move upward, and moves to a side close to the profile by the driving of the horizontal driving cylinder 2322, so that the profile is clamped by the clamping feeding mechanism 30, the first stop post 2314 and the second stop post 2325 are reset, that is, move downward to a height lower than the height of the belt transporting assembly 211, so that the profile is prevented from being collided with the clamping feeding mechanism 30, and the clamping mechanism 30 moves in the cutting direction 10.

In the embodiment of the present utility model, as shown in fig. 12 and 13, the clamping feeding mechanism 30 and the second supporting frame 22 are in sliding fit through a rack-and-pinion transmission mechanism, the clamping feeding mechanism 30 comprises a mounting seat 31, a third compression cylinder 32 and a third compression plate 33, wherein the mounting seat 31 is in sliding fit with the second supporting frame 22, and the mounting seat 31 is provided with a lower supporting plate 311; the third compression cylinder 32 is arranged at the top of the mounting seat 31; the third pressing plate 33 is connected with a piston rod of the third pressing cylinder 32, and the third pressing cylinder 32 drives the third pressing plate 33 to approach or separate from the lower support plate 311.

It can be appreciated that, after the profile is positioned by the first stop post 2314 and the second stop post 2325, the clamping and feeding mechanism 30 moves towards the direction of the profile, so that one end of the profile is located between the lower support plate 311 and the third pressing plate 33, the lower support plate 311 plays a supporting role on the bottom of the profile, and the third pressing cylinder 32 drives the third pressing plate 33 to move towards the direction of the lower support plate 311 and clamp and fix the profile. During the feeding of the clamping and feeding mechanism 30, the profile is clamped all the time by the third compacting plate 33 and the lower support plate 311.

In an embodiment of the present utility model, as shown in fig. 8 and 9, the profile cutting process line 100 further includes a scrap trailer 70, the scrap trailer 70 being located on a side of the second support frame 22 remote from the cutting mechanism 10. After the profile cannot be cut further, the clamp feed mechanism 30 is moved to an end remote from the cutting mechanism 10 and the profile is released so that the profile falls to the scrap trailer 70 for recycling. Further, for facilitating the falling of the profile, the clamping and feeding mechanism 30 is further provided with a pushing assembly, as shown in fig. 12 and 13, the pushing assembly comprises a pushing cylinder 34 and a pushing plate 35, the pushing cylinder 34 is arranged on the mounting seat 31, the pushing plate 35 is connected with a piston rod of the pushing cylinder 34, when the clamping and feeding mechanism 30 moves to the upper position of the waste trailer 70, the third pressing cylinder 32 loosens the profile, and the pushing cylinder 34 drives the pushing plate 35 to move, so that the profile is pushed forward to fall to the waste trailer 70.

In the embodiment of the present utility model, as shown in fig. 14 and 15, the processing mechanism 40 has a positioning jig assembly 41 for profile fixation, the positioning jig assembly 41 includes a moving base 411, a rotating base 412 and a clamping base, wherein the moving base 411 is driven by a power device to move on a horizontal plane; the rotating seat 412 is arranged on the movable base 411, and the rotating seat 412 is provided with a rotating connecting plate driven by a numerical control index plate 413 to realize rotation; the clamping seat is driven by the air cylinder to realize clamping, and the clamping seat is detachably arranged on the rotary connecting plate. The carrying robot 50 carries the cut section bar to the position of the clamping seat, clamping fixation is realized through the air cylinder, the milling cutter assembly 42 of the processing mechanism 40 carries out milling procedures or drilling procedures on the section bar, and the angle change of the section bar is realized through the rotation of the rotary connecting plate due to the fact that the processing surface of the section bar is more than one, so that the processing of different positions is convenient.

The foregoing description is only of the optional embodiments of the present utility model, and is not intended to limit the scope of the utility model, and all the equivalent structural changes made by the description of the present utility model and the accompanying drawings or the direct/indirect application in other related technical fields are included in the scope of the utility model.

Claims (10)

1. A profile cutting machining production line for automated processing of profiles, characterized in that the profile cutting machining production line comprises:

the cutting mechanism is used for cutting the section bar, and the opposite sides of the cutting mechanism are respectively provided with a feeding end and a discharging end;

the conveying and positioning mechanism is used for conveying and positioning the section bar and is positioned at one side of the feeding end;

the clamping and feeding mechanism is arranged at the tail end of the conveying and positioning mechanism and clamps the profile from the conveying and positioning mechanism to the cutting mechanism;

the processing mechanisms are used for processing the sectional materials and are arranged at one side of the discharging end at intervals;

and the transfer robot moves through the ground rail so as to transfer the profile of the discharge end to any processing mechanism.

2. The profile cutting machining line of claim 1, wherein the cutting mechanism comprises:

the workbench is provided with an installation cavity and a cutting groove communicated with the installation cavity, and the cutting groove is positioned between the feeding end and the discharging end;

the cutting machine is provided with a saw blade and is slidably arranged in the mounting cavity, so that the saw blade extends out of or retracts into the cutting groove;

the upper pressing component is used for pressing the top of the section bar and is arranged on the workbench;

the side compression assembly is used for compressing the side face of the section bar and is arranged on the workbench.

3. The profile cutting machining line of claim 2, wherein the side press assembly is in sliding engagement with the table to effect movement between the cutting slot and the discharge end.

4. A profile cutting machining line as claimed in claim 3, wherein the side press assembly comprises:

the sliding seat is in sliding fit with the workbench;

the sliding cylinder is arranged on the workbench;

the driving plate is arranged on the sliding seat and is connected with a piston rod of the sliding cylinder;

the first compression cylinder is arranged on the sliding seat;

the first compacting plate is arranged on a piston rod of the first compacting cylinder.

5. The profile cutting machining line of claim 2, wherein the upper compression assembly comprises:

the supporting seat is arranged on the workbench;

the second pressing cylinder is arranged on the supporting seat;

the second compacting plate is arranged on a piston rod of the second compacting cylinder.

6. The profile cutting machining line of claim 1, wherein the conveying and positioning mechanism comprises:

the first support frame is provided with a plurality of belt conveying assemblies at intervals;

the second support frame is arranged at intervals in front and back of the first support frame, the output end of the belt conveying assembly is positioned above the second support frame, and the clamping feeding mechanism is in sliding fit with the second support frame;

the positioning assemblies are arranged in a plurality and spaced mode on the second supporting frame.

7. The profile cutting processing line of claim 6, wherein the positioning assembly comprises a first stop assembly and a second stop assembly, the profile being defined between the first stop assembly and the second stop assembly;

the first fender material subassembly includes:

the first connecting plate is arranged on the second supporting frame;

the first lifting cylinder is arranged on the first connecting plate;

the roller seat is positioned above the first connecting plate and is connected with a piston rod of the first lifting cylinder;

the first material blocking column is abutted with the front side of the section bar and is arranged on the roller seat;

the second keeps off material subassembly includes:

the second connecting plate is arranged on the second supporting frame;

the horizontal driving cylinder is arranged on the second connecting plate;

the adjusting seat is in sliding fit with the second connecting plate and is connected with a piston rod of the horizontal driving cylinder;

the second lifting cylinder is arranged on the adjusting seat;

and the second material blocking column is in butt joint with the rear side of the section bar and is connected with a piston rod of the second lifting cylinder.

8. The profile cutting machining line according to claim 6, wherein a sliding fit is achieved between the clamping feeding mechanism and the second supporting frame through a rack and pinion transmission mechanism, the clamping feeding mechanism comprising:

the mounting seat is in sliding fit with the second supporting frame and is provided with a lower supporting plate;

the third compression cylinder is arranged at the top of the mounting seat;

the third compacting plate is connected with a piston rod of the third compacting cylinder, and the third compacting cylinder drives the third compacting plate to be close to or far away from the lower supporting plate.

9. The profile cutting process line of claim 6, further comprising a scrap trailer positioned on a side of the second support frame remote from the cutting mechanism.

10. The profile cutting machining line according to any one of claims 1 to 9, characterized in that the machining means has a positioning jig assembly for profile fixation, the positioning jig assembly comprising:

the movable base is driven by the power device to move on a horizontal plane;

the rotating seat is arranged on the movable base and is provided with a rotating connecting plate driven by a numerical control dividing plate to realize rotation;

the clamping seat is driven by the air cylinder to realize clamping, and the clamping seat is detachably arranged on the rotating connecting plate.