CN115446607A - Comprehensive processing device for hole sites of aluminum alloy profiles - Google Patents

Abstract

The invention provides a comprehensive hole site processing device for aluminum alloy profiles, and relates to the field of multifunctional processing platforms. A hole site comprehensive processing device for aluminum alloy profiles comprises a front conveyor, a feeding mechanism, a processing platform, a rear conveyor and a controller, wherein the feeding mechanism is arranged at the tail end of the front conveyor and comprises a feeding frame, and a bearing table is arranged at the top of the feeding frame; the processing platform comprises a reference table top and a plurality of rows of suspensions mounted on the top, and a plurality of groups of linear driving groups corresponding to the second long grooves are arranged at the bottom of the processing platform; and a pushing device is arranged on one side, far away from the feeding mechanism, of the processing platform, and the rear conveyor is arranged on one side, opposite to the pushing device. The invention has the beneficial effects that: the invention integrates the procedures of drilling, tapping, reaming, polishing and the like of the section bar, thereby improving the processing efficiency; meanwhile, the device adopts a transverse conveying processing and positioning mode, the length of a production line is shortened, and the production cost is reduced.

Description

Comprehensive processing device for hole sites of aluminum alloy profiles

Technical Field

The invention mainly relates to the field of multifunctional processing platforms, in particular to a comprehensive hole site processing device for aluminum alloy sections.

Background

The assembly type building adopts a modularized design, has the advantages of convenient disassembly and short construction time, and is widely applied to various building main bodies at present. The partition keel frame of the assembly wall body adopts aluminum alloy sections with light weight and high strength. For the processing of the aluminum alloy section, the aluminum alloy section is mainly sawed into regular sizes according to the requirement, and operations such as drilling, reaming, tapping and the like are carried out on the aluminum alloy section, so that the mounting hole, the wire passing hole and the like on the aluminum alloy section are perfected. At present, the processing of the aluminum alloy section is mostly finished by adopting an in-line processing line, namely, drilling machines, broaching machines, tapping machines, polishing machines and the like with various specifications are arranged on a straight line, and the section is positioned and processed when passing through each processing area along with the vertical conveying of the section. For example, chinese patent No. (CN 216138472U): a continuous drilling and tapping device for sectional materials is characterized in that a drilling machine and a tapping machine are arranged along the axis of the sectional materials, and the sectional materials are processed by drilling and tapping along with progressive conveying of the sectional materials. The equipment is suitable for processing the section with larger length and size, realizes automatic production to a certain extent, and reduces the participation of manpower. However, such in-line processing lines have the following problems: the drilling machine and the tapping equipment can only finish part of processing each time, and the processing efficiency is lower. Once equipment such as a drilling machine, a tapping machine and the like is added to improve the efficiency, the length of a production line can be lengthened, the occupied area of the equipment is increased, and the production cost is improved.

Disclosure of Invention

In order to solve the defects of the prior art, the invention provides a comprehensive processing device for hole sites of aluminum alloy sections, which is suitable for processing sections with shorter length applied in an assembly type building, and can respectively complete the procedures of drilling, tapping, reaming, polishing and the like, thereby improving the processing efficiency; meanwhile, the device adopts a transverse conveying processing and positioning mode, so that the length of a production line is greatly shortened, and the production cost is reduced.

In order to achieve the purpose, the invention is realized by the following technical scheme:

a comprehensive hole site machining device for aluminum alloy profiles comprises a front conveyor, a feeding mechanism, a machining platform, a rear conveyor and a controller, wherein the feeding mechanism is arranged at the tail end of the front conveyor, the feeding mechanism comprises a feeding frame, a bearing table is arranged at the top of the feeding frame, two parallel first long grooves are formed in the top surface of the bearing table, a pair of conveying chains are arranged at the bottom of the feeding frame, driving sprockets and driven sprockets are arranged at two ends of each conveying chain, a driving shaft is coaxially arranged on the two driving sprockets, a servo driving device for driving the driving shaft is arranged on the feeding frame, a plurality of push plates are uniformly arranged on the outer side of each conveying chain, the push plates penetrate through the first long grooves and are exposed on the top surface of the bearing table, and the push plates on the two conveying chains are symmetrically arranged; the processing platform comprises a reference table top and a plurality of rows of suspensions mounted on the top crane, suspension slide rails and suspension lead screws are horizontally arranged on the suspensions, suspension servo motors used for driving the suspension lead screws are arranged on one sides of the suspensions, a plurality of drill bases are arranged on the suspension slide rails in a sliding mode, intermittent lead screw nuts matched with the suspension lead screws are connected onto the drill bases, one of a drilling machine, a tapping machine, a hole expanding machine or a polishing machine is arranged on the drill bases in a sliding mode, and a pushing oil cylinder used for driving the drilling machine, the tapping machine, the hole expanding machine or the polishing machine to vertically reciprocate in a linear motion is arranged at the top of each drill base; the top surface of the processing platform is provided with a plurality of pairs of second long grooves, the bottom of the processing platform is provided with a plurality of groups of linear driving groups corresponding to the second long grooves, each linear driving group comprises a pair of screw rod transmission devices consisting of a linear seat, a linear screw rod and a linear guide rail, a driving seat is arranged on each linear guide rail in a sliding mode, a lifting clamp is arranged on each driving seat, the lifting clamps are matched with the second long grooves, and the pair of linear screw rods share the same linear servo motor; a material pushing device is arranged on one side, far away from the feeding mechanism, of the processing platform, and the rear conveyor is arranged on the opposite side of the material pushing device; the servo driving device, the suspension servo motor, the intermittent screw nut, the drilling machine, the tapping machine, the broaching machine, the polishing machine, the linear servo motor and the material pushing device are all in signal connection with the controller.

The intermittent screw nut comprises a limiting shell, a nut inner shell and an electromagnetic locker, the nut inner shell is rotatably connected in the limiting shell, the electromagnetic locker is arranged on one side of the limiting shell, and a brake pin is arranged on the electromagnetic locker and is abutted against the nut inner shell after the electromagnetic locker is electrified.

The positioning device comprises a base table top, a positioning cylinder, a positioning slide rail, a positioning pin and a positioning slide rail, wherein the bottom of the front end of the base table top is provided with the positioning cylinder and the vertical positioning slide rail, the front end of a cylinder rod of the positioning cylinder is provided with a group of positioning pins, the positioning pins are connected with the positioning slide rail in a sliding mode, and the positioning pins can penetrate through the base table top and be exposed above the base table top.

An end face cylinder is arranged at one end of the reference table top, an end face positioning plate is arranged at the front end of a cylinder rod of the end face cylinder, and the end face positioning plate is matched with the end face of the section.

The lifting clamp can pass through the second long groove and then be exposed above the machining platform.

The lifting fixture comprises two claw fixtures driven by an air cylinder and a sliding table air cylinder, and the sliding table air cylinder is arranged between a driving seat and the two claw fixtures.

And a positioning sensor corresponding to the suspension is arranged on the processing platform and is electrically connected with the controller.

And the plurality of linear driving groups are arranged from the center of the processing platform to two sides in a diffusion mode.

Compared with the prior art, the invention has the beneficial effects that:

the invention integrates the processing of hole drilling, tapping and polishing of the fabricated building keel sectional material and the processing of hole drilling and reaming of the line passing hole into a whole, and converts the existing vertical displacement processing line into a transverse processing line, so that each procedure can be synchronously processed, the connection of each procedure is smoother, and the efficiency of sectional material processing is greatly improved.

The reversing device realizes reversing of the sectional materials after the sectional materials are transversely conveyed and processed, optimizes layout of a workshop, saves length and space occupied by workshop equipment and saves construction cost.

Drawings

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

FIG. 2 is a schematic top view of the present invention;

FIG. 3 is a schematic top view of a processing platform according to embodiment 1 of the present invention;

FIG. 4 is a schematic structural diagram of a main view of a processing platform in embodiment 1 of the present invention;

FIG. 5 is a schematic top view of a processing platform according to embodiment 2 of the present invention;

FIG. 6 is a schematic view of the linear drive group arrangement of the present invention;

FIG. 7 is a schematic view of the construction of the drilling rig of the present invention;

FIG. 8 is a schematic view of a locating pin according to the present invention;

FIG. 9 is an enlarged view of the part A of the present invention;

FIG. 10 is an enlarged view of the part B of the present invention;

FIG. 11 is an enlarged view of the section C of the present invention;

FIG. 12 is a schematic structural view of the profile of the present invention;

reference numerals shown in the drawings: 1. a pre-conveyor; 2. a feeding mechanism; 3. a processing platform; 4. a rear conveyor; 5. a suspension; 6. a drill base; 7. a reference table top; 8. a material pushing device; 21. a feeding frame; 22. a bearing platform; 23. a first elongated slot; 24. a conveyor chain; 25. a servo drive device; 26. pushing the plate; 31. a linear drive group; 32. a linear seat; 33. a linear lead screw; 34. a linear guide rail; 35. a driving seat; 36. lifting the clamp; 37. a linear servo motor; 38. a second elongated slot; 51. a suspension rail; 52. a suspension lead screw; 53. a suspension servo motor; 61. an intermittent lead screw nut; 62. a drilling machine; 63. a tapping machine; 64. a hole expanding machine; 65. polishing the machine; 66. pushing the oil cylinder; 71. positioning the air cylinder; 72. positioning the slide rail; 73. positioning pins; 74. an end face cylinder; 75. an end face positioning plate; 361. a two-jaw clamp; 362. a sliding table cylinder; 611. a limiting shell; 612. a nut inner shell; 613. an electromagnetic locker.

Detailed Description

The invention will be further described with reference to the accompanying figures 1-12 and the specific embodiments. It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. Further, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teaching of the present invention, and these equivalents also fall within the scope of the present application.

Example 1:

the invention discloses an aluminum alloy section hole site comprehensive processing device which comprises a front conveyor 1, a feeding mechanism 2, a processing platform 3, a rear conveyor 4 and a controller. The front conveyor 1 is a connecting and conveying device for the section bar to be sawed and then to be conveyed to the processing platform 3, and the rear conveyor 4 is a connecting and conveying device for the section bar to be conveyed to a subsequent stacking procedure after being processed and finished by the processing platform 3. The feeding mechanism 2 is connected to the tail end of the front conveyor 1 and used for converting the axial conveying of the front conveyor 1 into transverse conveying and feeding the processing platform 3 as a buffer. The controller is as the control mechanism of each action part of this production line, and machining platform 3 is the machining platform that the section bar was carried out drilling, reaming, tapping and polishing. The front conveyor 1 and the rear conveyor 4 can adopt belt conveyors or roller conveyors, and the front conveyor 1 and the rear conveyor 4 are arranged on the same side of the processing platform 3, so that the front and rear section bars are conveyed in a reversing manner before and after being processed, the length of a section bar processing line is greatly shortened, and the occupation of production space is reduced.

The feeding mechanism 2 is arranged at the tail end of the front conveyor 1, the feeding mechanism 2 is in butt joint with the front conveyor 1, and the sectional materials conveyed by the front conveyor 1 are received and transferred. The feeding mechanism 2 comprises a feeding frame 21, a bearing table 22 is arranged at the top of the feeding frame 21, two parallel first long grooves 23 are formed in the top surface of the bearing table 22, and the first long grooves 23 are perpendicular to the conveying direction of the front conveyor 1. The far end of the bearing table 22 is provided with a contact sensor which is used for detecting whether the section bar is in place or not. The bottom of the feeding frame 21 is provided with a pair of conveying chains 24, two ends of each conveying chain 24 are provided with a driving chain wheel and a driven chain wheel, and the driving chain wheel and the driven chain wheels are rotatably connected with the bottom of the bearing table 22. The two driving sprockets are coaxially provided with a driving shaft, the feeding frame 21 is provided with a servo driving device 25 for driving the driving shaft, and the servo driving device 25 can drive the driving shaft to rotate so as to drive the two conveying chains 24 to synchronously operate. A plurality of push plates 26 are uniformly arranged on the outer side of the conveying chains 24, the push plates 26 penetrate through the first long grooves 23 and are exposed on the top surface of the bearing table 22, and the push plates 26 on the two conveying chains 24 are symmetrically arranged. By means of the action of the servo drive 25, the push plates 26 of the two conveyor chains 24 can be synchronized in order to drive the profile transversely. The running direction of the conveying chain 24 is perpendicular to the conveying direction of the front conveyor 1, and the controller can control the action of the servo driving device 25, so that when the conveying chain 24 is halted, the front conveyor 1 conveys the profile between two adjacent push plates 26, after the profile triggers the contact sensor, the contact sensor transmits a signal to the controller, and then the controller controls the action of the conveying chain 24 to convey the profile transversely. The pre-conveyor 1 continues to convey the profiles onto the loading table 22, pushed by the subsequent pusher 26 for transverse conveyance. The feeding mechanism 2 serves as a buffering component and can buffer the section, and continuity of multifunctional processing of the section on the subsequent processing platform 3 is guaranteed.

The processing platform 3 is arranged at the tail end of the feeding mechanism 2 and used for carrying the sectional material transversely conveyed by the feeding mechanism 2 and serving as a processing position of the sectional material. The processing platform 3 comprises a reference table top 7 and a plurality of rows of suspensions 5 mounted on the top, wherein the reference table top 7 is used as a positioning processing surface of the section bar, and the suspensions 5 are used as mounting positions of processing action components. And the suspension 5 top crane is arranged on a portal frame or a workshop top crane frame.

The bottom of the front end of the reference table top 7 is provided with a positioning cylinder 71 and a vertical positioning slide rail 72, the front end of a cylinder rod of the positioning cylinder 71 is provided with a group of positioning pins 73, the positioning pins 73 are slidably connected with the positioning slide rail 72, and the positioning pins 73 can pass through the reference table top 7 and be exposed above the reference table top 7. The positioning pin 73 is used as an initial positioning device for the section bar, and when the section bar is conveyed onto the reference table top 7 by the feeding mechanism 2, the positioning pin 73 limits the section bar to ensure that the section bar is aligned. An end face cylinder 74 is installed at one end of the reference table top 7, an end face positioning plate 75 is installed at the front end of a cylinder rod of the end face cylinder 74, a positioning edge is arranged on one side, opposite to the end face positioning plate 75, of the reference table top 7, the end face positioning plate 75 corresponds to the end face of the profile, and the end face positioning plate 75 can be used for pushing the profile to enable one end of the profile to be tightly attached to the positioning edge on the other side of the reference table top 7. After the positioning of the section bar is completed, the lifting clamp 36 clamps the section bar, and the positioning cylinder 71 drives the positioning pin 73 to slide downwards along the positioning slide rail 72, so that the section bar is not exposed above the reference table-board 7. The lifting fixture 36 then transports the profile to the machining position under the drive of a linear servo motor 37.

A suspension sliding rail 51 and a suspension lead screw 52 are horizontally arranged on the suspension 5, a suspension servo motor 53 for driving the suspension lead screw 52 is arranged on one side of the suspension 5, and the suspension servo motor 53 is connected with one end of the suspension lead screw 52 through a coupler. The suspension slide rail 51 is provided with a plurality of drill bases 6 in a sliding manner, the drill bases 6 are connected with intermittent lead screw nuts 61 matched with suspension lead screws 52, and the suspension servo motor 53 can drive the drill bases 6 to linearly move along the suspension slide rail 51 in a reciprocating manner by driving the suspension lead screws 52 through the intermittent lead screw nuts 61. The intermittent lead screw nut 61 may be intermittently engaged to provide an intermittent engagement with the hanger lead screw 52.

Specifically, the intermittent screw nut 61 comprises a limiting shell 611, a nut inner shell 612 and an electromagnetic locker 613, wherein a limiting cavity is arranged in the limiting shell 611, and limiting edges are arranged at two ends of the limiting cavity and limit the nut inner shell 612 arranged in the limiting cavity, so that the nut inner shell 612 is rotatably mounted in the limiting shell 611. The electromagnetic locker 613 is installed at one side of the limiting shell 611, and the electromagnetic locker 613 is provided with a brake pin, when the electromagnetic locker 613 is powered on, the brake pin pops out, the end of the brake pin is abutted against the nut inner shell 612, and the nut inner shell 612 and the limiting shell 611 are locked by friction force. When the nut inner shell 612 and the limiting shell 611 are relatively fixed, the rotation of the suspension lead screw 52 can drive the intermittent lead screw nut 61 to drive the drill base 6 to reciprocate linearly along the suspension slide rail 51. When the electromagnetic locker 613 is de-energized, the brake pin contracts and releases the interference with the nut inner shell 612, and at this time, the suspension screw 52 can only drive the nut inner shell 612 to rotate in the limit cavity of the limit shell 611.

One of a drilling machine 62, a tapping machine 63, a reamer 64 or a polishing machine 65 is slidably arranged on the drill base 6. In this embodiment, the suspension 5 has four rows, 3 to 4 drilling machines 62 are installed on the suspension 5 in the first row, and the drilling machine 62 can perform drilling operation on the installation hole and the wire passing hole on the profile, generally speaking, the diameter of the drill 62 of the wire passing hole is larger than that of the drill 62 of the installation hole. The second row of hangers 5 is provided with a tapping machine 63 corresponding to the mounting hole, and a tap of the tapping machine 63 performs a corresponding tapping operation on the mounting hole. And a hole expanding machine 64 corresponding to the wire through hole is arranged on the third row of the suspension 5, a milling cutter is arranged on a rotating shaft of the hole expanding machine 64, and the wire through hole drilled by the drilling machine 62 is processed by milling, so that the wire through hole on the section bar is expanded into a long hole. The polishing machines 65 corresponding to the screw holes are installed on the suspension frames 5 in the fourth row, conical soft polishing heads are installed on rotating shafts of the polishing machines 65, the soft polishing heads polish the screw holes and brush out burrs inside the screw holes, and the situation that bolts cannot be screwed in during subsequent installation is avoided. The reference table 7 below the machining positions corresponding to the drilling machine 62, the tapping machine 63, the reaming machine 64, and the polishing machine 65 has a long hole as a machining space for a drill, a tap, a milling cutter, and a polishing head. In this embodiment, three positioning sensors are sequentially mounted in a front-rear direction below the first row of suspensions 5, the distance between the front and rear positioning sensors is equal to the transverse distance between the pair of mounting holes, and the middle positioning sensor is mounted right in the middle between the front and rear positioning sensors. Wherein, the front and the back positioning sensors are used for processing and positioning a pair of mounting holes in the width direction of the sectional material, and the middle positioning sensor is used for processing and positioning the wire passing hole. A pair of positioning sensors are arranged below the second row and the fourth row of suspensions 5 in a front-back sequential manner, and the distance between the two positioning sensors is consistent with the distance between the front positioning sensor and the rear positioning sensor in the first row of suspensions. And a positioning sensor is arranged below the third row of suspensions 5 and used for reaming and positioning the wire through hole. In this embodiment, the positioning sensor is electrically connected to the controller, and the controller is configured to receive a signal from the positioning sensor and then control the operation of each of the operation elements.

And a pushing oil cylinder 66 for driving the drilling machine 62, the tapping machine 63, the broaching machine 64 or the polishing machine 65 to vertically reciprocate and linearly is arranged at the top of the drilling machine base 6, and the processing unit is pushed downwards by the pushing oil cylinder 66, so that the corresponding processing such as drilling, tapping, broaching or polishing is completed on the section.

A plurality of pairs of second long grooves 38 are formed in the top surface of the processing platform 3, and a plurality of linear driving sets 31 corresponding to the second long grooves 38 are mounted at the bottom of the processing platform 3. The number of the linear drive groups 31 corresponds to the number of the columns of the suspension 5. In this embodiment, the plurality of linear driving sets 31 are arranged from the center of the processing platform 3 to both sides in a diffused manner, that is, the plurality of linear driving sets 31 are arranged in a nested manner.

Each group of the linear driving groups 31 is used for driving one section bar, so that the section bar is continuously processed among a plurality of working procedures, and the processing efficiency of the section bar is improved. The linear driving group 31 includes a pair of screw rod transmission devices composed of a linear seat 32, a linear screw rod 33 and a linear guide rail 34, the linear guide rail 34 is slidably mounted with a driving seat 35, the driving seat 35 is mounted with a lifting clamp 36, and the lifting clamp 36 can pass through a second long groove 38 and then be exposed above the processing platform 3. The pair of linear screw rods 33 share the same linear servo motor 37, and the linear servo motor 37 is used for synchronously driving the two linear screw rods 33 to synchronously rotate, so that the two driving seats 35 can be driven to synchronously run along the linear guide rail 34. The linear servo motor 37 is connected with a speed reducer with double output shafts, and two output shafts of the speed reducer with double output shafts drive the linear screw 33 to rotate through a transmission mechanism respectively. Because the two linear screws 33 are arranged on two sides, the output shafts of the speed reducers of the double output shafts cannot coaxially drive the linear screws 33, so that in the embodiment, the linear screws 33 can be driven by connecting the universal coupling with the driving rod, the flexible transmission shafts can be connected to the output shafts and the end parts of the linear screws 33 for driving, and the linear screws 33 can be driven to rotate by the transmission chain wheels. In the embodiment, the driving rod is finally selected to drive, and two ends of the driving rod are respectively connected to the end of the output shaft and the end of the linear screw 33 through universal couplings.

The lifting fixture 36 includes a cylinder-driven two-jaw fixture 361 and a slide table cylinder 362, and the slide table cylinder 362 is disposed between the driving seat 35 and the two-jaw fixture 361. The two-jaw gripper 361 is used to grip the profile so that the profile can be driven in a linear motion along the linear guide 34 in response to the action of the driving seat 35. The sliding table cylinder 362 can drive the two-jaw clamp 361 to extend out of the second long groove 38, so that the sectional material can be clamped. After the profile is machined, the two-jaw clamp 361 releases the clamping of the profile, then the sliding table air cylinder 362 contracts, the two-jaw clamp 361 slides downwards to the position below the second long groove 38, and then the linear servo motor 37 rotates in the reverse direction, so that the two-jaw clamp 361 moves to the initial position to be ready.

And a pushing device 8 is arranged on one side of the processing platform 3, which is far away from the feeding mechanism 2, and the rear conveyor 4 is arranged on one side opposite to the pushing device 8. The material pushing device 8 can select a side cylinder, when the section material is processed, the side cylinder just stays between a push rod of the material pushing device 8 and the feeding mechanism 2, and the section material can be pushed to the feeding mechanism 2 to be conveyed to the next procedure through the pushing of the material pushing device 8.

In this embodiment, the servo driving device 25, the suspension servo motor 53, the intermittent lead screw nut 61, the drilling machine 62, the tapping machine 63, the hole expanding machine 64, the polishing machine 65, the linear servo motor 37, and the pushing device 8 are all in signal connection with the controller.

Taking the layout of the embodiment as an example, when the automatic processing is performed on the installation holes and the wire passing holes of the section bar, the control flow of the automatic processing in time sequence is as follows: the front conveyor 1 sequentially conveys the vertically conveyed sectional materials to a bearing table 22 of the feeding mechanism 2, the controller controls a servo driving device 25 to drive a conveying chain 24 to intermittently operate, and the sectional materials are sequentially conveyed to the front end of a reference table top 7, and at the moment, the positioning pins 73 just limit the sectional materials; at the moment, the controller controls the driving seat 35 on one group of linear driving group 31 to reset, controls the lifting clamp 36 to clamp the sectional material at the initial position, controls the positioning cylinder 71 to drive the positioning pin 73 to sink below the reference table-board 7, controls the linear servo motor 37 to drive the driving seat 35 on the linear driving group 31 to move downstream, and controls the positioning cylinder 71 to lift the positioning pin 73 to the upper side of the reference table-board 7 to carry and limit the subsequent sectional material.

When the lifting clamp 36 drives the profile to be positioned below the first row of suspensions 5, drilling holes of two rows of mounting holes at two ends of the profile and drilling holes of at least one wire passing hole in the middle of the profile are completed by using the drilling machine 62 on the first row of suspensions 5 through the positioning of the three positioning sensors; when two rows of mounting holes are drilled, the intermittent lead screw nut 61 on the drilling machine 62 for drilling the mounting holes is electrified, the intermittent lead screw nut 61 on the drilling machine 62 for drilling the through holes is powered off, the suspension servo motor 53 is controlled by the controller to drive the suspension lead screw 52 and drive the drilling machine 62 for drilling the mounting holes to move, and the drilling operation of the rows of mounting holes is completed; when the number of the mounting holes at the two ends of the section bar is different, and the extra mounting holes are drilled, the intermittent screw nut 61 on the drilling machine 62 at the side is electrified, and the intermittent screw nut 61 on the drilling machine 62 at the other side is powered off. When the line-passing hole is drilled, the intermittent lead screw nut 61 on the drilling machine 62 for drilling the mounting hole is powered off, the intermittent lead screw nut 61 on the drilling machine 62 for drilling the line-passing hole is powered on, the suspension servo motor 53 is controlled by the controller to drive the suspension lead screw 52, the drilling machine 62 for drilling the line-passing hole is driven to move, the drilling operation of the line-passing holes is completed, and when only one line-passing hole is formed, the drilling machine 62 for drilling the line-passing hole is not required to be powered on. Then, when the lifting fixture 36 drives the profile to be positioned below the second row of suspension frames 5, the tapping operation of two rows of mounting holes is completed by using the tapping machine 63 on the second row of suspension frames 5 through the positioning of the two positioning sensors; at this time, the intermittent lead screw nut 61 on the tapping machine 63 is always in an energized state, the controller controls the suspension servo motor 53 to drive the suspension lead screw 52 to drive the tapping machine 63 to move, the tapping operation of the array of the plurality of mounting holes is completed, when the number of the mounting holes at the two ends of the section bar is different, and the excessive mounting hole tapping operation is performed, the intermittent lead screw nut 61 on the tapping machine 63 on the side is energized, and the intermittent lead screw nut 61 on the tapping machine 63 on the other side is de-energized. Then, the lifting fixture 36 drives the profile to be positioned below the third row of suspensions 5, and the reamer 64 on the third row of suspensions 5 is used for milling the wire through holes in the profile to form long holes through positioning of one positioning sensor; at this time, the intermittent lead screw nut 61 on the reamer 64 is always in the energized state. Then, the lifting fixture 36 drives the section bar to be positioned below the fourth row of suspension frames 5, and the polishing machine on the fourth row of suspension frames 5 is utilized to respectively perform polishing operation on two rows of mounting screw holes on the section bar through the positioning of the two positioning sensors; when the number of the mounting holes at the two ends of the section bar is different, and the polishing operation of the excessive mounting holes is carried out, the intermittent lead screw nut 61 on the polishing machine 65 at the side is electrified, and the intermittent lead screw nut 61 on the polishing machine 65 at the other side is powered off.

After finishing the final polishing, the lifting clamp 36 releases the clamping of the section bar, the controller controls the material pushing device 8 to push the section bar, so that the section bar is conveyed to the next process through the rear conveyor 4, and simultaneously the controller controls the lifting clamp 36 to descend below the reference table 7, and controls the linear driving group 31 to act to reset the driving seat 35, so as to carry on the next section bar.

Taking the second row of suspensions 5 as an example for tapping the profile, when the above-mentioned profile is machined, the other sets of linear drive units 31 clamp the other profiles under the first, third and fourth rows of suspensions to perform the drilling, reaming and polishing processes, i.e. the four processes are performed simultaneously. The time for synchronous processing of the four processes depends on the process time with the longest working time when the four processes are processed separately.

Example 2:

compared with embodiment 1, the number of columns of the suspension 5 in this embodiment is only three, and correspondingly, the number of the linear drive groups 31 is only three. 3-4 drilling machines 62 are arranged on the suspension 5 of the first column, and the drilling machines 62 can be used for drilling the mounting holes and the wire through holes in the section. The second row of hangers 5 is provided with a tapping machine 63 corresponding to the mounting hole, and a tap of the tapping machine 63 performs a corresponding tapping operation on the mounting hole. A hole expanding machine 64 corresponding to the wire through hole and a polishing machine 65 corresponding to the screw hole are installed on the suspension 5 in the third row, a milling cutter is installed on a rotating shaft of the hole expanding machine 64, the wire through hole drilled by the pre-drilling machine 62 is processed through milling, the wire through hole in the section bar is expanded into a long hole, a conical soft polishing head is installed on the rotating shaft of the polishing machine 65, the screw hole is polished by the soft polishing head, burrs in the screw hole are brushed out, and the situation that the bolt cannot be screwed in during subsequent installation is avoided. Since the polishing machine 65 polishes only the screw hole of the profile, the machining process thereof does not interfere with the stroke of the reamer 64, and thus the polishing and reaming operations can be combined, thereby saving the installation space of the hanger 5. However, before the process is combined, the total processing time of the polishing process and the reaming process needs to be considered, when only one wire through hole exists, the total processing time of the two processes is shorter than that of the tapping process, the two processes can be combined, so that the installation space is saved, and once the number of the wire through holes is larger than or equal to two, the processing time of the polishing process and the reaming process exceeds that of the tapping process, at the moment, the combining process can reduce the overall processing efficiency of the profile, so that the combining process of the polishing process and the reaming process is not recommended at the moment.

In this embodiment, three positioning sensors are sequentially mounted in a front-rear direction below the first row of suspensions 5, the distance between the front and rear positioning sensors in the row of three positioning sensors is equal to the lateral distance between the pair of mounting holes, and the middle positioning sensor is mounted at the middle of the front and rear positioning sensors. Wherein, the front and the back positioning sensors are used for processing and positioning a pair of mounting holes in the width direction of the sectional material, and the middle positioning sensor is used for processing and positioning the wire passing hole. A pair of positioning sensors are arranged below the second row and the fourth row of suspensions 5 in a front-back sequential manner, and the distance between the two positioning sensors is consistent with the distance between the front positioning sensor and the rear positioning sensor in the first row of suspensions. Three positioning sensors are arranged below the third row of the suspension 5, the distance between the front and the rear positioning sensors in the row of the three positioning sensors is equal to the transverse distance between the pair of mounting holes, and the middle positioning sensor is arranged in the middle of the front and the rear positioning sensors. The front positioning sensor and the rear positioning sensor are used for polishing and positioning two rows of mounting screw holes, and the middle positioning sensor is used for reaming and processing and positioning the wire passing hole. In this embodiment, the positioning sensor is electrically connected to the controller, and the controller is configured to receive a signal from the positioning sensor and then control the operation of each of the operation elements.

Claims (8)

1. The utility model provides an aluminum alloy ex-trusions hole site integrated processing device, includes leading conveyer (1), feeding mechanism (2), processing platform (3), rearmounted conveyer (4) and controller, its characterized in that: the feeding mechanism (2) is arranged at the tail end of the front conveyor (1), the feeding mechanism (2) comprises a feeding frame (21), a bearing table (22) is arranged at the top of the feeding frame (21), two parallel first long grooves (23) are formed in the top surface of the bearing table (22), a pair of conveying chains (24) is arranged at the bottom of the feeding frame (21), driving sprockets and driven sprockets are arranged at two ends of each conveying chain (24), a driving shaft is coaxially arranged on the two driving sprockets, a servo driving device (25) for driving the driving shaft is mounted on the feeding frame (21), a plurality of push plates (26) are uniformly arranged on the outer side of each conveying chain (24), the push plates (26) penetrate through the first long grooves (23) and are exposed on the top surface of the bearing table (22), and the push plates (26) on the two conveying chains (24) are symmetrically arranged; the processing platform (3) comprises a reference table top (7) and a plurality of rows of suspensions (5) mounted on a top crane, suspension slide rails (51) and suspension lead screws (52) are horizontally arranged on the suspensions (5), suspension servo motors (53) used for driving the suspension lead screws (52) are arranged on one sides of the suspensions (5), a plurality of drill bases (6) are arranged on the suspension slide rails (51) in a sliding mode, intermittent lead screw nuts (61) matched with the suspension lead screws (52) are connected onto the drill bases (6), one of drills (62), tapping machines (63), broaching machines (64) or polishing machines (65) is arranged on the drill bases (6) in a sliding mode, and pushing oil cylinders (66) used for driving the drills (62), the tapping machines (63), the broaching machines (64) or the polishing machines (65) to vertically reciprocate linearly are arranged at the tops of the drill bases (6); the top surface of the processing platform (3) is provided with a plurality of pairs of second long grooves (38), the bottom of the processing platform (3) is provided with a plurality of groups of linear driving groups (31) corresponding to the second long grooves (38), each linear driving group (31) comprises a pair of lead screw transmission devices consisting of a linear seat (32), a linear lead screw (33) and a linear guide rail (34), a driving seat (35) is arranged on each linear guide rail (34) in a sliding manner, a lifting clamp (36) is arranged on each driving seat (35), each lifting clamp (36) is adapted to each second long groove (38), and the linear lead screws (33) share the same linear servo motor (37); a material pushing device (8) is arranged on one side, far away from the feeding mechanism (2), of the processing platform (3), and the rear conveyor (4) is arranged on one side, opposite to the material pushing device (8); the servo driving device (25), the suspension servo motor (53), the intermittent lead screw nut (61), the drilling machine (62), the tapping machine (63), the hole expanding machine (64), the polishing machine (65), the linear servo motor (37) and the material pushing device (8) are in signal connection with the controller.

2. The aluminum alloy section hole site comprehensive processing device of claim 1, characterized in that: the intermittent screw nut (61) comprises a limiting shell (611), a nut inner shell (612) and an electromagnetic locker (613), wherein the nut inner shell (612) is rotatably connected in the limiting shell (611), the electromagnetic locker (613) is arranged on one side of the limiting shell (611), and the electromagnetic locker (613) is provided with a brake pin which is abutted against the nut inner shell (612) after the electromagnetic locker (613) is electrified.

3. The comprehensive hole site machining device for aluminum alloy profiles as claimed in claim 1, characterized in that: the positioning device is characterized in that a positioning cylinder (71) and a vertical positioning slide rail (72) are arranged at the bottom of the front end of the reference table top (7), a group of positioning pins (73) are arranged at the front end of a cylinder rod of the positioning cylinder (71), the positioning pins (73) are slidably connected with the positioning slide rail (72), and the positioning pins (73) can pass through the reference table top (7) and be exposed above the reference table top (7).

4. The comprehensive hole site machining device for the aluminum alloy sections as claimed in claim 1 or 3, characterized in that: an end face cylinder (74) is arranged at one end of the reference table top (7), an end face positioning plate (75) is arranged at the front end of a cylinder rod of the end face cylinder (74), and the end face positioning plate (75) is matched with the end face of the section.

5. The aluminum alloy section hole site comprehensive processing device of claim 1, characterized in that: the lifting clamp (36) can pass through the second long groove (38) and then be exposed above the machining platform (3).

6. The comprehensive hole site machining device for aluminum alloy profiles as claimed in claim 1, characterized in that: the lifting clamp (36) comprises two claw clamps (361) driven by an air cylinder and a sliding table air cylinder (362), and the sliding table air cylinder (362) is arranged between the driving seat (35) and the two claw clamps (361).

7. The comprehensive hole site machining device for aluminum alloy profiles as claimed in claim 1, characterized in that: and a positioning sensor corresponding to the suspension (5) is arranged on the processing platform (3), and the positioning sensor is electrically connected with the controller.

8. The comprehensive hole site machining device for aluminum alloy profiles as claimed in claim 1, characterized in that: and the plurality of linear driving groups (31) are arranged from the center of the processing platform (3) to two sides in a diffused manner.

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