CN111774316A

CN111774316A - Automatic press-in detection equipment for flange plate bearing

Info

Publication number: CN111774316A
Application number: CN202010767338.5A
Authority: CN
Inventors: 郁彬; 于洋; 周佳
Original assignee: Kunshan Aodelu Automation Technology Co ltd
Current assignee: Kunshan Aodelu Automation Technology Co ltd
Priority date: 2020-08-03
Filing date: 2020-08-03
Publication date: 2020-10-16

Abstract

The invention discloses automatic press-in detection equipment for a flange plate bearing, which comprises a machine table, a press-mounting line, a lettering detection line, a grabbing mechanism and a material distribution device, wherein the press-mounting line is arranged on the machine table; the press-fitting line comprises a transfer conveying line and a press arranged on the transfer conveying line, a flange plate to be pressed is conveyed along with the carrier, and a bearing is pressed into a bearing hole corresponding to the flange plate through the press; the lettering detection line comprises a third conveying rail for conveying the carriers, and a lettering machine for lettering and an industrial camera for quality detection of the pressed flange plate are arranged on the machine table at the third conveying rail; the invention can realize the automation and the continuity of the whole action process of pressing the bearing into the flange plate, lettering, detecting the lettering effect, detecting whether the threaded hole of the flange plate exists or not, and the like only by manually putting the carrier into the flange plate and the bearing, and has the advantages of stable operation, high precision and high production efficiency.

Description

Automatic press-in detection equipment for flange plate bearing

Technical Field

The invention belongs to the technical field of automation equipment, and particularly relates to automatic press-in detection equipment for a flange plate bearing.

Background

The process of pressing in the flange plate bearing in the prior art is as follows: the bearing and the flange plate are manually placed at the designated positions on the press, then the press is started, the action of pressing the bearing into the flange plate is realized, the whole product is possibly dangerous in the processes of placing and riveting, laser lettering is carried out on the pressed finished product, and finally, the lettering effect, the existence of a threaded hole of the flange plate and other actions are manually detected.

Therefore, those skilled in the art will be expected to develop a device capable of achieving the above-mentioned purpose, and achieve the automation degree of the whole operation process of pressing the bearing into the flange plate, lettering, detecting the lettering effect, detecting whether the threaded hole of the flange plate exists, and the like.

Disclosure of Invention

The invention mainly solves the technical problem of providing automatic pressing-in detection equipment for a flange plate bearing, which can realize the automation and continuity of the whole action process of pressing the bearing into the flange plate, lettering and detecting lettering effects, detecting whether a threaded hole of the flange plate exists or not, and the like only by manually putting a carrier into the flange plate and the bearing, and has the advantages of stable operation, high precision and high production efficiency.

In order to solve the technical problems, the invention adopts a technical scheme that: the invention provides automatic press-in detection equipment for a flange plate bearing, which comprises a machine table, a press-mounting line, a lettering detection line, a grabbing mechanism and a material distribution device, wherein the press-mounting line is arranged on the machine table; the grabbing mechanism is positioned at the downstream of the press-mounting line, the lettering detection line is positioned at the downstream of the grabbing mechanism, and the material distribution device is positioned at the downstream of the lettering detection line;

the press-mounting line comprises a transfer conveying line for transferring the carriers and a press arranged on the transfer conveying line, the flange plate to be pressed is conveyed along with the carriers, and the bearings are pressed into the bearing holes corresponding to the flange plate through the press;

the lettering detection line comprises a third conveying track for carrier conveying, the direction of the third conveying track is defined to be the X direction, and the direction perpendicular to the third conveying track is the Y direction;

the material distributing device comprises a material taking mechanism, a non-defective product conveying rail used for placing non-defective products, a defective product conveying bin used for placing defective products and a material taking driving unit capable of driving the material taking mechanism to translate along the Y direction, and the flange plate located on the third conveying rail is conveyed to the non-defective product conveying rail or the defective product conveying bin through the material taking driving unit driving the material taking mechanism.

The circulation conveying line comprises a first conveying rail, a second conveying rail, a connecting rail and a connecting platform, wherein the first conveying rail and the second conveying rail are parallel to each other and are used for conveying carriers, the connecting rail and the connecting platform can be used for connecting the first conveying rail and the second conveying rail, and the press is located at the press-mounting position of the second conveying rail;

the first conveying track is provided with a chain wheel and chain transmission structure and a limiting structure, the position of the carrier relative to the chain is limited through the limiting structure, and the carrier is driven to convey through the chain wheel and chain transmission structure;

the second conveying track is provided with a belt conveying structure and a limiting mechanism, the position of the carrier relative to a belt is limited through the limiting mechanism, and the carrier is driven to convey through the belt conveying structure;

the connecting track is positioned at one end of the first conveying track, and the connecting platform is positioned at the other end of the first conveying track;

conveying the carrier from the first conveying rail to the second conveying rail through a first conveying device and the connecting rail at one end of the first conveying rail;

and the other end of the first conveying track is used for conveying the carrier from the second conveying track to the first conveying track through a second conveying device and the connecting platform.

The support frame is mounted on a workbench, the support frame is connected with the support frame through a linear guide rail, the support frame is fixed on a belt through a connecting block, the limiting driving cylinder is mounted on the mounting seat, the limiting driving cylinder drives the limiting assembly to move up and down, and the limiting assembly is used for limiting the support plate.

The first material handling device comprises a mounting frame, a stirring seat and a Y-direction driving unit capable of driving the stirring seat to translate along the Y direction, the mounting frame is mounted at the end part of the first conveying track, the stirring seat is mounted on the mounting frame, and the stirring seat translates along the Y direction of the mounting frame;

one side of the stirring seat is aligned with the carrier, the stirring seat is driven by the Y-direction driving unit to translate along the Y direction to drive the carrier to translate, and the carrier is conveyed to the second conveying rail through the connecting rail.

Furthermore, a positioning device for positioning the carrier is arranged at the position of the second conveying track and the connecting platform, a first positioning mechanism is arranged at one side of the second conveying track in the Y direction, a second positioning assembly is arranged at one side of the second conveying track in the Y direction, the first positioning mechanism comprises a first positioning assembly and a first Z-direction driving unit capable of driving the first positioning assembly to move up and down, the first positioning assembly is positioned above the second conveying track, and the carrier is clamped through the first positioning assembly and the second positioning assembly to limit the movement of the carrier in the X direction;

a second positioning mechanism is arranged on one side of the second conveying track along the X direction and comprises a third positioning assembly and an overturning driving cylinder capable of driving the third positioning assembly to overturn, the driving overturning cylinder is mounted on the connecting platform, the third positioning assembly is driven by the overturning driving cylinder to tightly press the carrier from the upper part, and the movement of the carrier in the Z direction and the Y direction is limited;

the first positioning mechanism, the second positioning assembly and the second positioning mechanism form the positioning device.

The first Z-direction driving unit comprises a first Z-direction driving cylinder, a guide pillar and a guide sleeve, a driving rod of the first Z-direction driving cylinder is connected with the lower end of the guide pillar, the guide pillar is mounted on the guide sleeve, the first positioning assembly is mounted at the upper end of the guide sleeve, the guide sleeve is unchanged in the Z-direction relative position, and the guide pillar is driven to move up and down relative to the guide sleeve through the first Z-direction driving cylinder, so that the first positioning assembly is driven to move up and down.

The third positioning assembly comprises a positioning wheel and a positioning wheel mounting seat, the positioning wheel is mounted on the positioning wheel mounting seat, and the part, extending out of the positioning wheel mounting seat, of the lower surface of the positioning wheel forms an upper limit on the carrier;

the third positioning assembly further comprises a connecting block and a rotating shaft, the connecting platform is provided with two parallel strip-shaped grooves, the connecting platform is provided with a connecting frame, the connecting frame penetrates through the strip-shaped grooves, the upper surface of the connecting frame is flush with the connecting platform, the output end of the overturning driving cylinder is rotatably connected with the lower end of the connecting block, and the rotating shaft sequentially penetrates through the lower end of the positioning wheel mounting seat, the connecting frame and the connecting block;

when the driving end of the turnover driving cylinder retracts, the connecting block is driven to move, and two sides of the positioning wheel mounting seat can be perpendicular to the connecting platform to limit the carrier through transmission between the rotating shaft and the positioning wheel mounting seat;

when the driving end of the turnover driving cylinder extends out, the connecting block is driven to move, and through transmission between the rotating shaft and the positioning wheel mounting seat, two sides of the positioning wheel mounting seat can be clamped in the strip-shaped groove, and the circumferential surface of the positioning wheel faces upwards.

Furthermore, the grabbing mechanism comprises a clamping jaw, a clamping jaw driving air cylinder capable of driving the two parts of the clamping jaw to approach or separate, a clamping jaw lifting air cylinder capable of driving the clamping jaw to move up and down, and an X-direction driving unit capable of driving the clamping jaw to translate in the X direction.

The feed divider further comprises a material pushing mechanism, one end of the good product conveying track is in butt joint with a feed inlet of the defective product conveying bin, the material pushing mechanism is arranged on the good product conveying track, and the material pushing mechanism comprises a material pushing plate and a material pushing cylinder capable of pushing the material pushing plate to move;

grabbing a workpiece to be grabbed through a material fetching mechanism, and conveying the workpiece to the position right above a good product conveying rail through a material fetching driving unit;

defining one side of a defective product conveying bin as a left side, when the workpiece is a defective product, positioning the material pushing plate at the left end of the defective product conveying track, positioning the workpiece at the right side of the material pushing plate, driving the material pushing plate rightwards through the material pushing cylinder, and pulling the defective product to move rightwards along the defective product conveying track;

when the workpiece is a defective product, the workpiece is positioned on the left side of the material pushing plate, and the material pushing cylinder drives the material pushing plate leftwards to push the defective product to enter the defective product conveying bin.

The material taking mechanism comprises a material taking supporting claw, a supporting claw driving cylinder and a material taking driving cylinder, wherein the supporting claw driving cylinder can drive the material taking supporting claw to be opened or close to the material taking supporting claw, the material taking driving cylinder can drive the material taking supporting claw to ascend and descend vertically, and the supporting claw driving cylinder drives the supporting claw to open a through hole formed in the flange plate to clamp the flange plate so as to fix the flange plate.

The invention has the beneficial effects that:

the flange plate cutting machine comprises a machine table, a press-mounting line, a lettering detection line, a grabbing mechanism and a material distributing device, wherein the press-mounting line is arranged on the machine table; the press-mounting line comprises a transfer conveying line for transferring the carriers and a press arranged on the transfer conveying line, the flange plate to be pressed is conveyed along with the carriers, and the bearings are pressed into the corresponding bearing holes of the flange plate through the press; the lettering detection line comprises a third conveying rail used for conveying a carrier, a lettering machine used for lettering and an industrial camera used for detecting the quality of the pressed flange plate are arranged on the machine platform, the flange plate and the bearing are manually placed on the carrier, the flange plate and the bearing plate to be pressed are conveyed to the press through a circulation conveying line, the flange plate and the bearing plate are pressed and mounted, and then a grabbing mechanism grabs the flange plate to the lettering detection line for subsequent processing; meanwhile, the belt carrier of the circulating conveying line reflows to the original position to prepare the next action process; in the process of the lettering detection line, the third conveying track drives the carriers to flow, lettering, appearance detection and the like are sequentially carried out, and finally, blanking is carried out at the position of the material distributing device according to good products and defective products; therefore, the invention can realize the automation and the continuity of the whole action process of pressing the bearing into the flange plate, lettering, detecting the lettering effect, detecting whether the threaded hole of the flange plate exists or not, and the like only by manually putting the carrier into the flange plate and the bearing, and has stable operation, high precision and high production efficiency; moreover, the labor is greatly saved, and the cost is reduced.

The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical solutions of the present invention more clearly understood and to implement them in accordance with the contents of the description, the following detailed description is given with reference to the preferred embodiments of the present invention and the accompanying drawings.

Drawings

FIG. 1 is an external view of the present invention;

FIG. 2 is one of the schematic structural views of the present invention (from an angle);

FIG. 3 is a second schematic view of the present invention (from another perspective)

FIG. 4 is a top view of the present invention;

FIG. 5 is an enlarged view of portion A of FIG. 2;

FIG. 6 is an external view (from an angle) of the flow conveyor line of the present invention;

FIG. 7 is a schematic view of the structure of the flow conveyor line of the present invention (from another perspective);

FIG. 8 is a schematic view of the arrangement of the first transfer device of the flow transfer conveyor line of the present invention;

fig. 9 is a schematic structural view of the transfer conveyor line of the present invention at the toggle seat;

fig. 10 is a schematic view of the first material handling device of the circulation conveying line of the invention;

fig. 11 is an external view at the positioning device of the circulation conveying line of the present invention;

fig. 12 is a schematic view of the structure at the positioning device of the flow transfer line of the present invention;

fig. 13 is a schematic view of the structure at the first positioning mechanism of the flow conveyor line of the present invention;

fig. 14 is one of the schematic structural views (from above) at the second positioning mechanism of the flow-around conveyor line of the present invention;

fig. 15 is one of the schematic structural views (as viewed from the bottom) at the second positioning mechanism of the flow-around conveyor line of the present invention;

fig. 16 is a schematic view of the structure at the first conveying rail of the circulation conveying line of the present invention;

fig. 17 is a schematic view of the mechanism at the stop mechanism of the flow conveyor line of the present invention (from another perspective);

FIG. 18 is one of the external views of the feed divider of the present invention (from an angle);

FIG. 19 is a schematic view of the construction of a feed divider of the present invention (from another perspective);

FIG. 20 is a top view of a feed divider of the present invention;

FIG. 21 is a schematic view of the structure at the take-off mechanism of the feed-out device of the present invention;

fig. 22 is a schematic structural view of the feed device of the invention at the good product conveying track (the arrow indicates the conveying direction of the bad product);

the parts in the drawings are marked as follows:

carrier 100, flange plate 200, bearing hole 2001 and machine 300;

the conveying device comprises a circulating conveying line 400, a first conveying rail 10, a second conveying rail 20, a material handling device 30, a mounting frame 301, a first limiting piece 3011, a connecting rail 302, a shaft sleeve 3021, a toggle seat 303, a triangular plate 3031, a vertical plate 3032, a second limiting piece 30321, a Y-direction driving unit 304, a leveling structure 305 and a roller 3051;

the positioning device 40, a first positioning mechanism 401, a first positioning assembly 4011, a first Z-direction driving unit 4012, a first Z-direction driving cylinder 40121, a guide pillar 40122, a guide sleeve 40123, a second positioning assembly 402, a limiting pillar mounting seat 4021, a limiting pillar 4022, a second positioning mechanism 403, a third positioning assembly 4031, a positioning wheel 40311, a portion 403111 of the lower surface of the positioning wheel extending out of the positioning wheel mounting seat, a positioning wheel mounting seat 40312, a connecting block 40313, a rotating shaft 40314, a connecting platform 4032, a strip-shaped groove 40321, a connecting frame 40322, an output end 40331 of an overturning driving cylinder and a sensor 404;

the device comprises a limiting structure 501, a limiting mechanism 502, a supporting frame 5021, a supporting seat 5022, a limiting driving cylinder 5023, a limiting assembly 5024, a fixed block 5025 and a motor 503;

the device comprises a material distributing device 60, a material taking mechanism 601, a material taking supporting claw 6011, a supporting claw driving cylinder 6012, a material taking driving cylinder 6013, a good product conveying rail 602, a defective product conveying bin 603, a feeding hole 6031, a roller 6032, a material pushing mechanism 604, a material pushing plate 6041, a material pushing cylinder 6042, a fixed sleeve 6043 and a sliding rod 6044;

the gripping mechanism 70, a clamping jaw 701, a clamping jaw driving cylinder 702 and a clamping jaw lifting cylinder 703;

a press 80;

a third conveying track 90, a carving machine 901, a first industrial camera 902, and a second industrial camera 903;

the mask body 500, an installation protection plate 5001, an installation grating 5002 and a feeding area 5003.

Detailed Description

The following description of the embodiments of the present invention is provided for illustrative purposes, and the present invention will be described in detail with reference to the accompanying drawings. The invention may be embodied in other different forms, i.e. it is capable of various modifications and changes without departing from the scope of the invention as disclosed.

In this embodiment, fig. 18, 19, 20 and 22 all show the positions of the stripper plates when the flange plate is good.

Example (b): an automatic press-in detection device for a flange plate bearing is shown in fig. 1 to 22 and comprises a machine table 300, a press-mounting line, a lettering detection line, a grabbing mechanism 70 and a material distribution device 60, wherein the press-mounting line is arranged on the machine table, the grabbing mechanism is used for placing a flange plate to the lettering detection line from the press-mounting line, and the material distribution device is used for distinguishing good products from defective products; the grabbing mechanism is positioned at the downstream of the press-mounting line, the lettering detection line is positioned at the downstream of the grabbing mechanism, and the material distribution device is positioned at the downstream of the lettering detection line;

as shown in fig. 1 to 4, the press-fitting line includes a transfer conveyor 400 for transferring carriers and a press 80 provided in the transfer conveyor, and a flange plate to be press-fitted is conveyed along with the carriers, and a bearing is pressed into a corresponding bearing hole of the flange plate by the press;

the lettering detection line comprises a third conveying track 90 for conveying the carriers; (in this embodiment, the transmission manner of the third conveying track is not described in detail for the reason of the prior art, i.e., the motor 503 and the sprocket drive the chain to reciprocate, and the carrier is fixedly mounted on the chain to follow the chain; in this embodiment, to save power, the same motor drives the third conveying track and the chain on the second conveying track to reciprocate), the direction of the third conveying track is defined as the X direction, the direction perpendicular to the third conveying track is defined as the Y direction, a carving machine 901 (in the embodiment, the carving machine is a laser carving machine) for carving characters and industrial cameras for quality detection of the pressed flange plate are arranged at the third conveying track of the machine table (in the embodiment, two industrial cameras are arranged, namely a first industrial camera 902 and a second industrial camera 903 respectively and are respectively positioned at two sides of the third conveying track;

the material distribution device comprises a material taking mechanism 601, a good product conveying rail 602 for placing a good product, a defective product conveying bin 603 for placing a defective product and a material taking driving unit capable of driving the material taking mechanism to translate along the Y direction, and the flange plate located on the third conveying rail is conveyed to the good product conveying rail or the defective product conveying bin through the material taking driving unit driving material taking mechanism.

As shown in fig. 6 to 7, the circulation conveying line includes a first conveying rail 10 and a second conveying rail 20 which are parallel to each other and are used for conveying the carriers 100, and a connecting rail 302 and a connecting platform 4032 which can connect the first conveying rail and the second conveying rail, and the press is located at a press-fitting position of the second conveying rail;

the first conveying track is provided with a chain wheel and chain transmission structure (which is not described in detail in the prior art, and the chain is driven by a motor 503 and a chain wheel to reciprocate) and a limiting structure 501, the position of the carrier relative to the chain is limited by the limiting structure, and the carrier is driven by the chain wheel and chain transmission structure to be conveyed;

the second conveying track is provided with a belt conveying structure (which is not described in detail in the prior art, and the belt is driven to reciprocate by matching of a motor 503 and a driving wheel and a driven wheel) and a limiting mechanism 502, the position of the carrier relative to the belt is limited by the limiting mechanism, and the carrier is driven to convey by the belt conveying structure;

In this embodiment, limit structure is for installing in a plurality of stoppers of chain, the carrier can be located between two adjacent stoppers, will through the stopper the carrier is for the position of chain is injectd.

As shown in fig. 16 to 17, the limiting mechanism 502 includes a support bracket 5021, a support bracket 5022, a limiting driving cylinder 5023, a limiting assembly 5024 and a fixing block 5025, the support bracket is mounted on a workbench, the support bracket is connected with the support bracket through a linear guide rail, the support bracket is fixed to a belt through a connecting block, the limiting driving cylinder is mounted on the mounting base, the limiting driving cylinder drives the limiting assembly to move up and down, and the limiting assembly limits the carrier plate.

In this embodiment, the carrier is provided with a limiting hole, the limiting component is a limiting column head matched with the limiting hole, and the limiting column head is inserted into the limiting hole to limit the carrier, so that the carrier is conveyed along with a belt.

As shown in fig. 8 to 10, the first material handling device 30 includes a mounting frame 301, a dial base 303, and a Y-direction driving unit 304 capable of driving the dial base to translate in the Y direction, the mounting frame is mounted at an end of the first conveying rail, the dial base is mounted on the mounting frame, and the dial base translates in the Y direction along the mounting frame;

one side of the stirring seat is aligned with the carrier, the stirring seat is driven by the Y-direction driving unit to translate along the Y direction to drive the carrier to translate, and the carrier is conveyed to the second conveying rail through the connecting rail. In this embodiment, the Y-direction driving unit is a cylinder, but is not limited thereto.

In this embodiment, the structure of the second material conveying device is similar to that of the first material conveying device, and therefore, the description is omitted, and different structures may be adopted as long as the carriers can be conveyed from the second conveying rail to the first conveying rail.

In this embodiment, by using the first material handling device, an automatic operation mode is adopted to carry materials (such as carriers) between two parallel conveying rails, so that a square-shaped conveying track of the materials is conveniently realized, and the space requirement of mechanical equipment can be met; secondly, a large amount of labor is saved.

As shown in fig. 8 to 10, the mounting frame is provided with a leveling structure 305 for leveling a workpiece placed on the carrier directly above the connecting rail;

the leveling structure includes a rotatable roller 3051, which is located directly above the connecting track.

Leveling mechanism's advantage: for example, the distance of cylinder apart from the orbital upper surface of connection has been set for in advance, and if during the blowing, the bearing is not aimed at the dead eye completely, and one side of bearing can the perk, and when the carrier passed through the cylinder, the cylinder can be with the bearing of dislocation a little in the dead eye, corrects to a certain extent because artifical blowing position is inaccurate problem, avoids follow-up placing inaccurate because of the material, and the material that the pressure equipment caused is scrapped etc

As shown in fig. 8 to 10, two sides of the connecting track are each provided with a rotatable bushing 3021 for assisting the translation of the vehicle.

The workpieces are a flange plate 200 and bearings (not shown) placed in bearing holes 2001 of the flange plate. The distance between the roller and the upper surface of the connecting rail is preset, if the material is discharged, the bearing is not completely aligned to the bearing hole, one side of the bearing can be tilted, and when a carrier passes through the roller, the roller can push the slightly dislocated bearing into the bearing hole.

As shown in fig. 8 to 10, a first stopper 3011 for limiting the moving stroke of the Y-direction driving unit is disposed on a side of the mounting frame close to the first conveying rail.

As shown in fig. 8 to 10, the dial seat includes a triangular plate 3031 and a vertical plate 3032, the triangular plate is connected with the vertical plate, and one side surface of the triangular plate is parallel to the side surface of the carrier.

As shown in fig. 8 to 10, the vertical plate is provided with a second stopper 30321 for limiting the movement stroke of the Y-direction drive unit.

As shown in fig. 11 to 15, a positioning device 40 for positioning a carrier is disposed at the second conveying track and the connecting platform, a first positioning mechanism 401 is disposed at one side of the second conveying track and in the Y direction, a second positioning assembly 402 is disposed at one side of the second conveying track and in the Y direction, the first positioning mechanism includes a first positioning assembly 4011 and a first Z-direction driving unit 4012 capable of driving the first positioning assembly to move up and down, the first positioning assembly is located above the second conveying track, and the carrier is clamped by the first positioning assembly and the second positioning assembly to limit the movement of the carrier in the X direction;

a second positioning mechanism 403 is arranged on one side of the second conveying track along the X direction, the second positioning mechanism comprises a third positioning assembly 4031 and an overturning driving cylinder (not shown in the figure) capable of driving the third positioning assembly to overturn, the driving overturning cylinder is mounted on the connecting platform, the third positioning assembly is driven by the overturning driving cylinder to press the carrier from above, and the movement of the carrier in the Z direction and the Y direction is limited;

As shown in fig. 11 to 15, each of the first positioning assembly and the second positioning assembly includes a limiting post mounting seat 4021 and a plurality of limiting posts 4022, and the limiting posts are mounted on the limiting post mounting seats, so that the carrier is clamped from the X direction by the circumferential surface of the limiting post of the first positioning assembly and the circumferential surface of the limiting post of the second positioning assembly.

In the embodiment, the carrier is positioned and limited from multiple directions through the first positioning mechanism, the second positioning assembly and the second positioning mechanism, and the carrier on the conveying channel and the workpiece placed on the carrier are separated automatically through the cooperation of other mechanisms, so that the carrier cannot be taken up when the workpiece is grabbed, the carrier can be conveniently reflowed and the subsequent process of the workpiece is facilitated, and a large amount of labor is saved.

As shown in fig. 11 to 15, the first Z-direction driving unit includes a first Z-direction driving cylinder 40121, a guide pillar 40122 and a guide sleeve 40123, wherein a driving rod of the first Z-direction driving cylinder is connected to a lower end of the guide pillar, the guide pillar is mounted on the guide sleeve, the first positioning assembly is mounted on an upper end of the guide sleeve, a relative position of the guide sleeve in the Z direction is unchanged, and the first Z-direction driving cylinder drives the guide pillar to move up and down relative to the guide sleeve, so as to drive the first positioning assembly to move up and down.

As shown in fig. 11-15, the third positioning assembly includes a positioning wheel 40311 and a positioning wheel mount 40312, the positioning wheel is mounted on the positioning wheel mount, and a portion 403111 of the lower surface of the positioning wheel extending beyond the positioning wheel mount forms an upper limit for the carrier;

the third positioning assembly further comprises a connecting block 40313 and a rotating shaft 40314, the connecting platform is provided with two parallel strip-shaped grooves 40321, the connecting platform is provided with a connecting frame 40322, the connecting frame penetrates through the strip-shaped grooves, the upper surface of the connecting frame is flush with the connecting platform, the output end 40331 of the overturning driving cylinder is rotatably connected with the lower end of the connecting block, and the rotating shaft sequentially penetrates through the lower end of the positioning wheel mounting seat, the connecting frame and the connecting block;

when the driving end of the turnover driving cylinder extends out, the connecting block is driven to move, and through transmission between the rotating shaft and the positioning wheel mounting seat, two sides of the positioning wheel mounting seat can be clamped in the strip-shaped groove, and the circumferential surface of the positioning wheel faces upwards. In this embodiment, the turning driving cylinder is mounted on the connecting frame. In this embodiment, the connecting block is fixed with the rotating shaft, the positioning block mounting seat is relatively fixed with the rotating shaft, and the connecting frame is rotatably connected with the rotating shaft through a bearing.

As shown in fig. 11 to 15, in the present embodiment, the workpiece to be processed placed by the carrier 100 is a flange plate 200, the carrier is provided with a flange plate hole, the flange plate is placed in the flange plate hole, and the upper surface of the flange plate is protruded on the upper surface of the carrier. In this embodiment, the bearing is press-fitted in the bearing hole of the flange plate, and a sensor 404 for detecting whether the carrier is in place is further disposed at the positioning device.

As shown in fig. 6 and 16, it is defined that the conveying line in the embodiment conveys clockwise, and the side where the connecting platform is located is the right, and the right side of the first conveying track is also provided with a first positioning mechanism 401, which is used for performing temporary limiting when the carriers are conveyed to the first conveying track by the second conveying device, so as to avoid position deviation and influence on the following circulation process.

As shown in fig. 5, the gripping mechanism 70 includes a clamping jaw 701, a clamping jaw driving cylinder 702 capable of driving two parts of the clamping jaw to approach or separate from each other, a clamping jaw lifting cylinder 703 capable of driving the clamping jaw to move up and down, and an X-direction driving unit (not shown) capable of driving the clamping jaw to translate in the X direction. The X-direction driving unit may be driven by an air cylinder or a motor screw, and is not described in detail for the prior art.

As shown in fig. 18 to 22, the material distribution device further includes a material pushing mechanism 604, one end of the good product conveying rail is in butt joint with the feeding hole 6031 of the defective product conveying bin, the material pushing mechanism is disposed on the good product conveying rail, and the material pushing mechanism includes a material pushing plate 6041 and a material pushing cylinder 6042 capable of pushing the material pushing plate to move;

grabbing a workpiece to be grabbed (not shown) through a material fetching mechanism, and conveying the workpiece to be grabbed to the position right above a good product conveying rail through a material fetching driving unit;

As shown in fig. 18 to 22, the material taking mechanism includes a material taking supporting jaw 6011, a supporting jaw driving cylinder 6012 capable of driving the material taking supporting jaw to open or close, and a material taking driving cylinder 6013 capable of driving the material taking supporting jaw to lift up and down, and the flange plate is fixed by driving the supporting jaw to open a through hole on which the flange plate is clamped. (in this embodiment, the workpiece is a flange plate with a bearing pressed therein, and the through hole is a through hole of the bearing, but the invention is not limited thereto, and other workpieces with similar structures can adopt the structure.)

The defective product conveying bin is a bin inclined downwards from the feeding end.

As shown in fig. 18 to 22, the bottom of the defective product conveying bin is provided with a plurality of rows of rollers (6032) for allowing the defective products to slide down.

As shown in fig. 18 to 22, the material taking driving unit is a motor screw transmission mechanism (not shown), and the material taking mechanism is driven to translate along the Y direction by the motor screw transmission mechanism.

As shown in fig. 18 to 22, the pushing mechanism further includes a fixing sleeve 6043 and a sliding rod 6044, the fixing sleeve is sleeved on the sliding rod, the fixing sleeve is installed on the good product conveying rail, one end of the sliding rod is connected with the pushing plate, and the sliding rod can slide along the sliding sleeve.

And the two groups of material pushing mechanisms are respectively positioned on two sides of the good product conveying track. (two sets of the devices have more reasonable structures and are more stable when pushing the workpiece, and one set of the devices can also realize the basic material pushing function.)

In the embodiment, the material distribution device can realize the respective discharging of good products and defective products of workpieces (such as flange plates) through the design of mechanisms such as the material taking mechanism, the good product conveying track, the defective product conveying bin, the material pushing mechanism and the like, so that the subsequent reworking, re-inspection and the like are facilitated, and the automation degree of the automatic press-fitting equipment for the flange plate bearing is improved; and a large amount of labor is saved, and the device has the characteristics of simple structure, high speed, high efficiency, stable quality and the like.

As shown in fig. 1, in this embodiment, the indentation detection apparatus further includes a cover 500, the cover covers the periphery of the workbench, the left end of the first conveying track is a feeding area 5003, an installation protection plate 5001 is arranged on one side of the cover and in the feeding area, and the installation protection plate isolates an operating area of an operator from an operating area of the apparatus. This design completely isolates the operator from the movement mechanism.

As shown in fig. 1, the cover body is provided with an installation grating 5002 for detecting whether an operator leaves an operation area at the installation protection plate, and the two safety gratings are electrically connected with a control system of the press-in detection device. If the human body part does not leave the operation interval, the equipment cannot be started, and the safety of the equipment is improved.

The detection equipment that impresses is equipped with and must both hands press simultaneously and just can start two start button (not shown in the figure) of the detection equipment that impresses, two start button (not shown in the figure) are connected with the control system electricity of the detection equipment that impresses.

Need the operator to press two start button simultaneously during the action, the check out test set work of impressing has further guaranteed that outside the equipment was arranged in completely to the operator when equipment work began, and the design of a start button is better than current, is favorable to avoiding because of unexpected touching the start button makes the condition that equipment began to operate, can promote operator's personal safety, reduces the emergence of incident.

The working principle and the working process of the invention are as follows:

manually placing the flange plate and the bearing on a carrier, conveying the flange plate and the bearing plate to be pressed to a press through a circulation conveying line, pressing the flange plate and the bearing plate, and then grabbing the flange plate to a lettering detection line by a grabbing mechanism to perform subsequent processing; meanwhile, the belt carrier of the circulating conveying line reflows to the original position to prepare the next action process; in the process of the lettering detection line, the third conveying track drives the carriers to flow, lettering, appearance detection and the like are sequentially carried out, and finally, blanking is carried out at the position of the material distributing device according to good products and defective products;

the concrete working process of the transfer conveying line is as follows:

conveying the empty carrier to the end part (defined as the left end) of the first conveying track through the first conveying track (driven by a belt conveying structure), wherein at the moment, one side surface of a triangular plate of a shifting plate seat is just aligned with the side surface of the carrier, placing a flange plate of a bearing to be pressed and the bearing into the carrier, driving the shifting seat to translate along the Y direction by a Y-direction driving unit, driving the carrier to translate, conveying the carrier to a second conveying track through the auxiliary action of the connecting track and a shaft sleeve arranged on the connecting track, carrying out subsequent manufacturing procedures, driving the shifting seat to return by the Y-direction driving unit, and repeating the actions; in the process, when the carrier passes through the leveling mechanism, the distance between the roller and the upper surface of the connecting track is preset, if the carrier is discharged, the bearing is not completely aligned with the bearing hole, one side of the bearing can tilt, when the carrier passes through the roller, the roller can push the slightly dislocated bearing into the bearing hole, the problem of inaccurate manual discharging position is corrected to a certain extent, and material scrapping caused by subsequent material placement and press mounting due to inaccurate material placement is avoided;

the subsequent processes here refer to: the carrier is just clamped between limiting blocks arranged on the chain, then the carrier is driven by a chain wheel and chain transmission structure to move to a processing station (such as a press mounting station, a bearing is pressed into a flange plate through a press mounting machine), then the carrier is conveyed to the right end of a second conveying rail, namely a positioning device, after the sensor detects that the carrier is in place, a push rod of a first Z-direction driving cylinder retracts, a driving guide pillar moves upwards relative to a guide sleeve, so that a limiting column of a first positioning assembly is driven to extend upwards to the side face of the carrier, the carrier is clamped tightly through the matching of the limiting columns of the first positioning assembly and a second positioning assembly, and the movement of the carrier in the X direction is limited;

meanwhile, the driving end of the overturning driving cylinder retracts to drive the connecting block to move, and the two sides of the positioning wheel mounting seat can be perpendicular to the connecting platform through transmission between the rotating shaft and the positioning wheel mounting seat, namely, the part of the lower surface of the positioning wheel, which extends out of the positioning wheel mounting seat, presses the carrier from the upper part to form upper limit on the carrier, and limits the movement of the carrier in the Z direction and the Y direction to limit the carrier;

through the action process, the carrier is positioned, the carrier is prevented from moving, the flange plate after the bearing is pressed and mounted is taken away by matching with other mechanisms, if the positioning device is not provided, the function of taking away the flange plate independently can not be realized, and the flange plate taken away independently can be used for subsequent detection, laser lettering and the like;

then, the driving end of the overturning driving cylinder extends out to drive the connecting block to move, the two sides of the positioning wheel mounting seat can be clamped in the strip-shaped groove through transmission between the rotating shaft and the positioning wheel mounting seat, the circumferential surface of the positioning wheel faces upwards, interference of a carrier passing through the connecting platform is avoided, the carrier can be conveyed to the connecting platform through the second material conveying device, the carrier is conveyed to the right end of the first conveying rail through the second material conveying device, the first positioning component of the first positioning mechanism descends (the principle is the same as that of the positioning device), then the limiting driving cylinder of the limiting mechanism drives the limiting column head of the limiting component to extend into the limiting hole of the carrier to position the carrier, the carrier is conveyed to the left end of the first conveying rail through the belt transmission component, and the next process is repeated;

the working process of the material distributing device is as follows:

defining one side where a defective product conveying bin is located as a left side, describing the embodiment by taking a flange plate and a bearing as an example, after a material taking driving cylinder drives a material taking supporting claw to descend to the right position, the material taking supporting claw extends into a through hole of the bearing of the flange plate, then the supporting claw driving cylinder drives the material taking supporting claw to expand to grab the flange plate provided with the bearing, and the flange plate is conveyed to the right above a defective product conveying rail through a material taking driving unit; when the flange plate is a defective product, the flange plate is positioned on the left side of the material pushing plate, and the material pushing cylinder drives the material pushing plate leftwards to push the defective product to enter the defective product conveying bin.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent structures made by using the contents of the specification and the drawings of the present invention or directly or indirectly applied to other related technical fields are included in the scope of the present invention.

Claims

1. The utility model provides a flange board bearing automatic detection equipment that impresses which characterized in that: the flange plate cutting machine comprises a machine table (300), a press-mounting line, a lettering detection line, a grabbing mechanism (70) and a material distributing device (60), wherein the press-mounting line, the lettering detection line and the grabbing mechanism are arranged on the machine table; the grabbing mechanism is positioned at the downstream of the press-mounting line, the lettering detection line is positioned at the downstream of the grabbing mechanism, and the material distribution device is positioned at the downstream of the lettering detection line;

the press-fitting line comprises a transfer conveying line (400) for transferring the carriers and a press (80) arranged on the transfer conveying line, the flange plate to be pressed is conveyed along with the carriers, and the bearings are pressed into the corresponding bearing holes of the flange plate through the press;

the lettering detection line comprises a third conveying track (90) used for conveying the carriers, the direction in which the third conveying track is located is defined as the X direction, the direction perpendicular to the third conveying track is defined as the Y direction, and a lettering machine (901) used for lettering and an industrial camera used for detecting the quality of the pressed flange plate are arranged on the machine platform and at the third conveying track;

the material distribution device comprises a material taking mechanism (601), a good product conveying rail (602) for placing a good product, a defective product conveying bin (603) for placing a defective product and a material taking driving unit capable of driving the material taking mechanism to translate along the Y direction, and the flange plate located on the third conveying rail is conveyed to the good product conveying rail or the defective product conveying bin through the material taking driving unit driving material taking mechanism.

2. The automatic press-in detection device for the flange plate bearing according to claim 1, wherein: the circulation conveying line comprises a first conveying rail (10) and a second conveying rail (20) which are parallel to each other and used for conveying carriers (100), a connecting rail (302) and a connecting platform (4032) which can be used for connecting the first conveying rail and the second conveying rail, and the press is located at the press-mounting position of the second conveying rail;

the first conveying track is provided with a chain wheel and chain transmission structure and a limiting structure (501), the position of the carrier relative to the chain is limited through the limiting structure, and the carrier is driven to convey through the chain wheel and chain transmission structure;

the second conveying track is provided with a belt conveying structure and a limiting mechanism (502), the position of the carrier relative to the belt is limited through the limiting mechanism, and the carrier is driven to convey through the belt conveying structure;

3. The automatic press-in detection device for the flange plate bearing according to claim 2, wherein: the limiting mechanism (502) comprises a support frame (5021), a support seat (5022), a limiting driving cylinder (5023), a limiting assembly (5024) and a fixing block (5025), the support frame is installed on a workbench, the support seat is connected with the support frame through a linear guide rail, the support seat is fixed on a belt through a connecting block, the limiting driving cylinder is installed on the installation seat, the limiting driving cylinder drives the limiting assembly to move up and down, and the limiting assembly realizes limiting of the support plate.

4. The automatic press-in detection device for the flange plate bearing according to claim 2, wherein: the first material carrying device (30) comprises a mounting frame (301), a stirring seat (303) and a Y-direction driving unit (304) capable of driving the stirring seat to translate along the Y direction, the mounting frame is mounted at the end part of the first conveying track, the stirring seat is mounted on the mounting frame, and the stirring seat translates along the Y direction of the mounting frame;

5. The automatic press-in detection device for the flange plate bearing according to claim 2, wherein: the positioning device (40) used for positioning the carrier is arranged at the position of the second conveying track and the connecting platform, a first positioning mechanism (401) is arranged on one side of the second conveying track in the Y direction, a second positioning assembly (402) is arranged on one side of the second conveying track in the Y direction, the first positioning mechanism comprises a first positioning assembly (4011) and a first Z-direction driving unit (4012) capable of driving the first positioning assembly to move up and down, the first positioning assembly is positioned above the second conveying track, and the carrier is clamped through the first positioning assembly and the second positioning assembly to limit the movement of the carrier in the X direction;

a second positioning mechanism (403) is arranged on one side of the second conveying track along the X direction, the second positioning mechanism comprises a third positioning assembly (4031) and an overturning driving cylinder capable of driving the third positioning assembly to overturn, the driving overturning cylinder is mounted on the connecting platform, the third positioning assembly is driven by the overturning driving cylinder to tightly press the carrier from the upper side, and the movement of the carrier in the Z direction and the Y direction is limited;

6. The automatic press-in detection device for the flange plate bearing according to claim 5, wherein: the first Z-direction driving unit comprises a first Z-direction driving cylinder (40121), a guide pillar (40122) and a guide sleeve (40123), a driving rod of the first Z-direction driving cylinder is connected with the lower end of the guide pillar, the guide pillar is mounted on the guide sleeve, the first positioning assembly is mounted at the upper end of the guide sleeve, the guide sleeve is unchanged in the Z-direction relative position, and the guide pillar is driven by the first Z-direction driving cylinder to move up and down relative to the guide sleeve, so that the first positioning assembly is driven to move up and down.

7. The automatic press-in detection device for the flange plate bearing according to claim 1, wherein: the third positioning assembly comprises a positioning wheel (40311) and a positioning wheel mounting seat (40312), the positioning wheel is mounted on the positioning wheel mounting seat, and a part (403111) of the lower surface of the positioning wheel, which extends out of the positioning wheel mounting seat, forms an upper limit for the carrier;

the third positioning assembly further comprises a connecting block (40313) and a rotating shaft (40314), the connecting platform is provided with two parallel strip-shaped grooves (40321), the connecting platform is provided with a connecting frame (40322), the connecting frame penetrates through the strip-shaped grooves, the upper surface of the connecting frame is flush with the connecting platform, the output end (40331) of the overturning driving cylinder is rotatably connected with the lower end of the connecting block, and the rotating shaft penetrates through the lower end of the positioning wheel mounting seat, the connecting frame and the connecting block in sequence;

8. The automatic press-in detection device for the flange plate bearing according to claim 1, wherein: the grabbing mechanism (70) comprises a clamping jaw (701), a clamping jaw driving air cylinder (702) capable of driving two parts of the clamping jaw to approach or separate, a clamping jaw lifting air cylinder (703) capable of driving the clamping jaw to move up and down, and an X-direction driving unit capable of driving the clamping jaw to translate in the X direction.

9. The automatic press-in detection device for the flange plate bearing according to claim 1, wherein: the material distribution device further comprises a material pushing mechanism (604), one end of the good product conveying track is in butt joint with a feeding hole (6031) of the defective product conveying bin, the material pushing mechanism is arranged on the good product conveying track and comprises a material pushing plate (6041) and a material pushing cylinder (6042) capable of pushing the material pushing plate to move;

10. The automatic press-in detection device for the flange plate bearing according to claim 1, wherein: the material taking mechanism comprises a material taking supporting claw (6011), a supporting claw driving cylinder (6012) capable of driving the material taking supporting claw to open or close to the material taking supporting claw and a material taking driving cylinder (6013) capable of driving the material taking supporting claw to lift up and down, and the flange plate is fixed by driving the supporting claw driving cylinder to open a through hole formed in the flange plate to clamp the flange plate.