CN114313854A - Annular automation equipment detects assembly line - Google Patents

Abstract

An annular automation equipment detection assembly line comprises a rack, a track, a pressure-resistant test module, a retaining ring ejection detection module, a labeling module and a clamping mechanism, wherein the retaining ring ejection detection module is arranged on one side of the pressure-resistant test module along the outer side of the track in the clockwise direction; a plurality of chucks are arranged on the track; the pressure-resistant testing module, the retaining ring ejection detecting module, the labeling module and the clamping mechanism are sequentially arranged according to the advancing sequence of the chucks on the track, and the spacing distances are the same. The annular automatic equipment detection assembly line is arranged on the same assembly line through the pressure-resistant test module, the buckle ejection detection module and the labeling module, so that all detection items of workpieces can be completed by one assembly line, and workers only need to place the workpieces to be detected, so that the labor intensity of the workers is greatly reduced, and the detection efficiency is improved.

Description

Annular automation equipment detects assembly line

Technical Field

The invention relates to the technical field of detection assembly lines, in particular to a detection assembly line of annular automation equipment.

Background

The assembly line is an industrial production mode, and each production unit only focuses on the work of processing a certain fragment so as to improve the work efficiency and the yield. The assembly line is the most efficient way for industrial production at present, and in the production of electronic equipment, the production efficiency can be maximized by using the assembly line in view of the large number of electronic components and high complexity.

The electronic equipment that has now through assembly line production is generally through manual operation's mode, detects one by one to the electronic equipment on the assembly line. For the manual detection mode, defective products caused by improper manual operation are easily generated, such as insufficient pressure application degree during pressure testing.

Chinese patent CN201520005576.7 discloses a low-voltage start detection device for a low-power motor in an automatic assembly line. The device comprises an electrical parameter instrument, a connecting wire for connecting the electrical parameter instrument and a motor, and a data processing and analyzing device. The method comprises the steps of collecting an index value of the motor during low-voltage starting through an electric parameter instrument, and judging whether the motor is successfully started at low voltage through a data processing and analyzing device according to the collected index value.

According to the scheme, the purpose of automatic pressure resistance test can be achieved, but other project tests still need to be carried to another production line manually by operators, and the detection efficiency is low.

Disclosure of Invention

In view of the above, the present invention provides a detection assembly line for an annular automation device to solve the above technical problems.

An annular automatic equipment detection assembly line comprises a rack, a track arranged on the rack, a pressure-resistant test module arranged on the outer side of the track, a retaining ring ejection detection module arranged on one side of the pressure-resistant test module along the clockwise direction of the outer side of the track, a labeling module arranged on one side of the retaining ring ejection detection module, and a clamping mechanism arranged on one side of the labeling module; a plurality of chucks are arranged on the track; the pressure-resistant testing module, the retaining ring ejection detecting module, the labeling module and the clamping mechanism are sequentially arranged according to the advancing sequence of the chucks on the track, and the spacing distances are the same.

Furthermore, the voltage withstanding test module comprises a first support, and a first electricity testing module and a second electricity testing module which are arranged on two sides of the rail.

Furthermore, a sliding cylinder is arranged on the first support, and a conducting strip is arranged at the output end of the sliding cylinder.

Further, the first electricity testing module comprises a first base arranged on the rack, a first torsion spring support with one end connected with the base, and a first abutting wheel connected with the other end of the first torsion spring support; the second electricity measuring module comprises a second base arranged on the rack, a groove arranged on the end face of the rack and a second butting wheel rotatably arranged in the groove, wherein the groove is far away from the end face of the rack.

Furthermore, the buckle ejection detection module comprises a second support, a first lifting cylinder arranged in the second support, a guide rail arranged on the end face, facing the rail, of the second support, a sliding block in sliding joint with the guide rail, and a fixing plate connected with the sliding block and the first lifting cylinder.

Furthermore, two sliding grooves are formed in the end face, facing the sliding block, of the second support, and two side walls of the lifting cylinder extend out of the two sliding grooves.

Furthermore, a top abutting plate is arranged on the fixing plate, the top abutting plate faces the end face of the rack and is provided with a dynamometer, a top pillar is arranged at the end part, far away from the second support, of the dynamometer, and the central axis of the top pillar coincides with the central axis of the chuck.

Furthermore, mark the module and include a base, a set of setting is in position adjustment mechanism on the base, a setting is in base on the position adjustment mechanism, a set of setting is in feed subassembly on the base side end face, a setting is in feed mechanism on the base side end face, and a setting is in paste dress subassembly on the base side end face.

Further, press from both sides and get module and include a third support, a setting is in horizontal slip table on the third support, a setting is in second lift cylinder on the horizontal slip table, and a set of setting is in clamping jaw assembly on the second lift cylinder output.

Further, the clamping jaw assembly comprises a cross-shaped mounting frame which is connected with the output end of the second lifting cylinder and is provided with four mounting arms; each mounting arm is provided with at least one sliding groove, and a clamping jaw sliding block is arranged in each sliding groove in a clamping mode. And the clamping jaw sliding block is provided with a clamping jaw. And each clamping jaw and the clamping jaw sliding block are clamped and connected with each other through a gas blowing hole.

Compared with the prior art, the annular automation equipment detection assembly line provided by the invention has the advantages that the pressure resistance test module, the snap ring ejection detection module and the labeling module are arranged on the same assembly line, so that all detection items of workpieces can be completed by one assembly line, and workers only need to place the workpieces to be detected, so that the labor intensity of the workers is greatly reduced, and the detection efficiency is improved.

Drawings

Fig. 1 is a schematic structural diagram of a detection assembly line of an annular automation device provided by the present invention.

Fig. 2 is a schematic structural diagram of a voltage withstanding test module of the circular automation device inspection line of fig. 1.

Fig. 3 is an exploded view of a buckle ejection detection module of the detection assembly line of the ring-shaped automation device of fig. 1.

Fig. 4 is a schematic structural diagram of a labeling module of the detection line of the circular automation device of fig. 1.

Fig. 5 is a schematic structural diagram of a clamp mechanism of the detection line of the ring-shaped automation device of fig. 1.

Fig. 6 is a schematic view of a jaw structure of the clamping mechanism of fig. 5.

Detailed Description

Specific examples of the present invention will be described in further detail below. It should be understood that the description herein of embodiments of the invention is not intended to limit the scope of the invention.

As shown in fig. 1 to fig. 6, which are schematic structural diagrams of a detection assembly line of a ring-shaped automation device provided by the present invention. The detection assembly line of the annular automatic equipment comprises a rack 10, a track 20 arranged on the rack, a pressure-resistant test module 30 arranged outside the track 20, a buckle ejection detection module 40 arranged on one side of the pressure-resistant test module 30 along the clockwise direction outside the track 20, a labeling module 50 arranged on one side of the buckle ejection detection module 40, and a clamping mechanism 60 arranged on one side of the labeling module 50. It is contemplated that the loop automation device detection line may include other functional structures, such as fastening screws, lubricants, etc., which are well known to those skilled in the art and will not be described herein.

The rack 10 is used for carrying the rail 20, the pressure resistance testing module 30, the buckle ejection detecting module 40 and the labeling module 50, and arranging the above parts at a position where an operator feels comfortable when using the rack.

A plurality of chucks 21 are provided at intervals on the rail 20. The chuck 21 is symmetrically provided with a pair of limiting columns 211 which are used for being matched with preset holes of a workpiece to limit the movement of the workpiece, so that subsequent detection steps are facilitated. The chuck 21 is held by a roller to the rail 20, and the chuck 21 is moved along the rail 20. A driving motor 22, a driving pulley 23 disposed at the output end of the driving motor 22, a driven pulley 24 disposed at the other end of the inner side of the track 20, and a transmission belt 25 disposed on the driving pulley 23 and the driven pulley 24. The driving motor 22 drives the driving belt 25 to rotate.

The transmission belt 25 is fixedly connected with the bottom of the chuck 21. It is conceivable that the radius of curvature of the driving pulley 23 and the driven pulley 24 is the same as the radius of curvature of the two ends of the rail 20, so as to prevent the driving belt 25 from locking or damaging the apparatus when the chuck 21 is moved along the rail 20 by the driving belt 25.

The voltage withstanding test module 30 includes a first support 31 disposed on the rack 10, and a first electricity testing module 32 and a second electricity testing module 33 disposed on two sides of the rail 20. The first bracket 31 is provided with a sliding cylinder 311, and a conductive plate 312 is provided at an output end of the sliding cylinder 311. The sliding cylinder 311 is used for pushing the conducting strip 312 to contact with a workpiece to be detected, and conducting detection is performed. The first electricity testing module 32 and the second electricity testing module 33 are both connected with external control equipment through leads. The first and second electricity testing modules 32 and 33 can form a passage with a workpiece in a voltage withstanding test, namely, the passage formed by the first electricity testing module 32 and the workpiece is qualified in the voltage withstanding test, the passage formed by the second electricity testing module 33 and the workpiece is a defective product, and when the first and second electricity testing modules 32 and 33 form a passage, the priority of the signal of the second electricity testing module 33 is greater than that of the signal of the first electricity testing module 32, thereby avoiding the generation of misjudgment.

The first electricity measuring module 32 is disposed outside the rail 20, and includes a first base 321 disposed on the rack 10, a first torsion spring support 322 connected to the base 321 at one end, and a first contact wheel 323 connected to the first torsion spring support 322 at the other end. The first torsion spring support 322 is perpendicular to an end surface of the first base 321 facing away from the rack 10 in a natural state. When the first contact wheel 323 contacts with the bottom of the chuck 21, the first torsion spring support 322 bends toward the advancing direction of the chuck 21 and transmits a signal to an external control device, so that the chuck 21 stops operating, thereby facilitating detection. After the inspection step is completed, the chuck 21 is re-run and the workpiece is transported to the next inspection module. The control principle can be written by a PLC program or a singlechip, which is the prior art on the market and is not described herein again.

The second electricity measuring module 33 is arranged inside the track 20, and includes a second base 331 arranged on the rack 10, a second mounting bracket 332 arranged on the second base 331 near the end of the chuck 21, a second torsion spring bracket 333 with one end connected with the second mounting bracket 332, and a second butting wheel 334 with one end pivoted with the second torsion spring bracket 333. The opening of the second mounting bracket 332 is disposed toward the side wall of the chuck 21 so that the second abutment wheel 334 abuts the side wall of the chuck 21. And the second torsion spring support 333 and the pivot shaft of the second mounting support 332 are also provided with torsion springs.

The retaining ring ejection detection module 40 includes a second bracket 41, a first lifting cylinder 42 disposed in the second bracket 41, a guide rail 43 disposed on an end surface of the second bracket 41 facing the rail 20, a slider 44 slidably engaged with the guide rail 43, and a fixing plate 45 connected to the slider 44 and the first lifting cylinder 42.

Two sliding grooves 411 are formed in the end surface of the second bracket 41 facing the slider 44, and two side claws of a lifting claw 421 provided on the lifting cylinder 42 respectively extend out of the two sliding grooves 411 and are connected to the fixed plate 45. The end surface of the slide block 44 facing away from the guide rail 43 is connected to the fixing plate 45, so that the lifting cylinder 42 drives the slide block 44 and the fixing plate 45 to move up and down.

The fixed plate 45 is provided with a top abutting plate 451, a force measuring device 46 is arranged on the end surface of the top abutting plate 451 facing the rack 10, a top pillar 461 is arranged at the end part of the force measuring device 46 far away from the second bracket 41, and the central axis of the top pillar 461 coincides with the central axis of the chuck 21, so that the top pillar 461 coincides with the central area of the workpiece when the ejection force is tested. The load cell 46 moves up and down together with the fixing plate 45, so as to achieve the purpose of testing the ejection pressure.

The labeling module 50 comprises a base 51, a group of orientation adjusting mechanisms 52 arranged on the base 51, a base 53 arranged on the orientation adjusting mechanisms 52, a group of feeding components 54 arranged on one side end face of the base 53, a feeding mechanism 55 arranged on one side end face of the base 53, and a mounting component 56 arranged on one side end face of the base 53.

The base 51 is used for raising the above parts to a height suitable for labeling. The base 51 is provided with a cavity for holding maintenance tools.

The orientation adjusting mechanism 52 includes a set of longitudinal adjusting mechanisms 521 disposed on the base 10, and a set of lateral adjusting mechanisms 522 disposed on the longitudinal adjusting mechanisms 521. The longitudinal adjustment mechanism 521 and the transverse adjustment mechanism 522 are each adjusted in position by a hand wheel 523 arranged on one side thereof.

The base 53 is L-shaped, an end surface perpendicular to the base 51 is an auxiliary surface 531, and the other end surface is located on an end surface of the transverse sliding table 5222 facing the base 53.

The auxiliary surface 531 is provided with a driving motor 532 and a plurality of mounting through holes 533. A dust cover 5312 is provided on the other end surface of the auxiliary surface 531. The mounting through hole 533 is used for mounting the feeding assembly 54 and the feeding mechanism 55. The dust cover 5312 is used to prevent foreign matter from falling between the driving motor 532 and a gear engaged therewith. The driving motor 532 is used for connecting with the feeding assembly 54 to provide driving force.

The feeding assembly 54 includes a feeding wheel 541 disposed on an end surface of the auxiliary surface 531 away from the base 51, a receiving wheel 542 disposed on one side of the feeding wheel 541, a set of clamping wheels 543 disposed on a side of a length of the auxiliary surface 531, and a plurality of tightening posts disposed on the auxiliary surface 531. The two sides of the feeding wheel 541 are provided with limit discs 5411 for rolling label stickers to be used. The receiving wheel 542 is used for rolling used label stickers, and the receiving wheel 542 is provided with an anti-falling device 5421. Anticreep device 5421 is used for preventing that the label sticker after the rolling from droing, and the operating personnel of being convenient for takes.

The clamping wheel set 543 is located between the material receiving wheel 542 and the base 51. The adhesive paper is used for keeping the smoothness of the adhesive paper of the label, so that the adhesive paper is convenient to adsorb. The tightening column 544 is used to keep the label sticker in a tightened state all the time during the transportation process, which is convenient for transportation. And both ends of the tightening column 544 are provided with a limiting flange 5441, which is also used for preventing the label sticker from sliding off.

The feeding mechanism 55 includes a mounting bracket 551 fixed on the auxiliary surface 531, a feeding cylinder 552 disposed on an end surface of the mounting bracket 551 facing away from the base 51, a feeding platform 553 disposed on an end portion of the feeding cylinder 552 facing the mounting module 56, and a transition module 554 disposed on the other end of the feeding cylinder 552.

The feed cylinder 552 drives the feed platform 553 and the transition member 554 to move axially. The feed platform 553 is used to feed unused label stamps and a roller 555 is provided on the end of the feed platform 553 facing the base 10. The used sticker is wound around the roller 555 and is wound on the winding wheel 542 along the other end face of the feeding cylinder 552. The transition assembly 554 is a transition frame coupled to one end of the feed cylinder 552 and a roller 555 disposed in the transition frame. Roller 555 is used for avoiding the label sticker to contact at rolling process and sharp-edged edge and lead to the fracture.

The mounting assembly 56 comprises a fixing support 561 arranged on the auxiliary surface 531, a lifting cylinder 562 arranged on the end surface of the fixing support 561, which is opposite to the feeding mechanism 55, an auxiliary support 563 arranged on the end surface of the lifting cylinder 562, which is opposite to the fixing support 561, and a telescopic cylinder 564 arranged on the end surface of the auxiliary support 563, which is opposite to the lifting cylinder 562, wherein an adsorption assembly 565 is arranged at the output end of the telescopic cylinder 564.

The fixing bracket 561 is used for supporting and mounting the above components. The lifting cylinder 562 drives the auxiliary bracket 563 to do axial movement, so that the height of the telescopic cylinder 564 is adjusted, and the applicability is improved. The telescopic cylinder 564 drives the adsorption component 565 to move up and down, the adsorption component 565 adsorbs the label sticker on the feeding platform 553 to the surface thereof in a negative pressure manner, and the label sticker is abutted against the surface of a product through the descending movement of the telescopic cylinder 564, thereby completing the label mounting. It is contemplated that the negative pressure principle of the adsorption assembly 565 is prior art in the market and will not be described herein. The end of the telescopic cylinder 564 facing away from the adsorption component 565 is provided with an adjusting nut 566, and an operator can change the preset height of the adsorption component 565 by screwing the adjusting nut 566, so that the telescopic cylinder 564 can be suitable for products with different heights.

The clamping mechanism 60 is disposed at an end of the rail 20 away from the pressure resistance testing module 30, and includes a third support 61, a sliding platform 62 disposed on the third support 61, a second lifting cylinder 63 disposed on the sliding platform 62, and a set of clamping jaw assemblies 64 disposed at an output end of the second lifting cylinder 63.

The third bracket 61 is a long rectangular metal plate fixed on the leg on one side of the rack 10 by screwing, two connecting plates 611 are arranged on two sides of the end part far away from the ground, and the other ends of the two connecting plates 611 are fixed with the sliding platform 62 by screwing. The second lifting cylinder 63 is vertically arranged on the sliding platform 62. A set of clamping jaw assemblies 64 is arranged on the output end of the second lifting cylinder 63.

The gripper assembly 64 includes a cross mount 641 having four mounting arms 642 attached to the output of the second lift cylinder 63. Each mounting arm 642 is provided with at least one sliding groove 643, and a clamping jaw sliding block 644 is clamped in each sliding groove 643. The clamping jaw sliding block 644 is provided with a clamping jaw 645. Each clamping jaw 645 and the clamping jaw sliding block 644 are provided with a gas blowing hole 646, the gas blowing hole 646 is connected with an external cylinder, and the clamping jaws 645 and the clamping jaw sliding blocks 644 are pushed to slide along the sliding grooves 643 through blowing gas, so that a workpiece is clamped.

When the device is used, an operator places a workpiece to be detected on the chuck 21, and the driving motor 22 drives the transmission belt 25 to operate through an external controller. Thereby driving the chuck 21 to operate and conveying the workpiece to the pressure-resistant testing module 30 and the retaining ring ejection detection module 40 in sequence for testing. If the result of one of the tests is a defective product, the program controls the driving motor 22 to reverse, so that the chuck 21 with the defective workpiece placed thereon moves in the reverse direction to reach the initial position, and the operator can take out the defective product and place a new workpiece. If the test result passes, the program will control the driving motor 22 to rotate, so that the chuck 21 advances a preset distance for the next test. And because the spacing distance between each test module is the same, and each the spacing distance between chuck 21 is the same to be convenient for adjust, reduce the quantity of sensor. Then, when the pressure-proof testing module 30 and the retaining ring ejection detecting module 40 both pass, the chuck 21 conveys the workpiece to the labeling module 50 for labeling. Of course, the labeling step can be adjusted according to actual requirements. Finally, the workpieces qualified in detection are clamped by the clamping mechanism 60 and placed on a material frame or a conveying belt.

Compared with the prior art, the annular automation equipment detection assembly line provided by the invention has the advantages that the pressure resistance test module 30, the snap ring ejection detection module 40 and the labeling module 50 are arranged on the same assembly line, so that all detection items of workpieces can be completed by one assembly line, and workers only need to place the workpieces to be detected, so that the labor intensity of the workers is greatly reduced, and the detection efficiency is improved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the scope of the present invention, and any modifications, equivalents or improvements that are within the spirit of the present invention are intended to be covered by the following claims.

Claims (10)

1. The utility model provides an annular automation equipment detects assembly line which characterized in that: the annular automatic equipment detection assembly line comprises a rack, a track arranged on the rack, a pressure-resistant test module arranged on the outer side of the track, a retaining ring ejection detection module arranged on one side of the pressure-resistant test module in the clockwise direction along the outer side of the track, a labeling module arranged on one side of the retaining ring ejection detection module, and a clamping mechanism arranged on one side of the labeling module; a plurality of chucks are arranged on the track; the pressure-resistant testing module, the retaining ring ejection detecting module, the labeling module and the clamping mechanism are sequentially arranged according to the advancing sequence of the chucks on the track, and the spacing distances are the same.

2. The ring automation device detection pipeline of claim 1, wherein: the pressure-resistant test module comprises a first support, a first electricity testing module and a second electricity testing module, wherein the first electricity testing module and the second electricity testing module are arranged on two sides of the track.

3. The ring automation device detection pipeline of claim 2, wherein: a sliding cylinder is arranged on the first support, and a conducting strip is arranged at the output end of the sliding cylinder.

4. The ring automation device detection pipeline of claim 2, wherein: the first electricity testing module comprises a first base arranged on the rack, a first torsion spring support with one end connected with the base, and a first butting wheel connected with the other end of the first torsion spring support; the second electricity measuring module comprises a second base arranged on the rack, a groove arranged on the end face of the rack and a second butting wheel rotatably arranged in the groove, wherein the groove is far away from the end face of the rack.

5. The ring automation device detection pipeline of claim 1, wherein: the buckle ejection detection module comprises a second support, a first lifting cylinder arranged in the second support, a guide rail arranged on the end face, facing the rail, of the second support, a sliding block in sliding joint with the guide rail, and a fixing plate connected with the sliding block and the first lifting cylinder.

6. The ring automation device detection pipeline of claim 5, wherein: two sliding grooves are formed in the end face, facing the sliding block, of the second support, and two side walls of the lifting air cylinder extend out of the two sliding grooves.

7. The ring automation device detection pipeline of claim 5, wherein: the fixed plate is provided with a top abutting plate, the top abutting plate faces the end face of the rack and is provided with a dynamometer, a top post is arranged at the end part of the dynamometer far away from the second support, and the central axis of the top post is coincided with the central axis of the chuck.

8. The ring automation device detection pipeline of claim 1, wherein: the labeling module comprises a base, a group of position adjusting mechanisms arranged on the base, a base arranged on the position adjusting mechanisms, a group of feeding components arranged on one side end face of the base, a feeding mechanism arranged on one side end face of the base and a labeling component arranged on one side end face of the base.

9. The ring automation device detection pipeline of claim 1, wherein: the clamping module comprises a third support, a transverse sliding table arranged on the third support, a second lifting cylinder arranged on the transverse sliding table, and a clamping jaw assembly arranged on the output end of the second lifting cylinder.

10. The ring automation device detection pipeline of claim 9, wherein: the clamping jaw assembly comprises a cross-shaped mounting frame connected with the output end of the second lifting cylinder and provided with four mounting arms; each mounting arm is provided with at least one sliding groove, and a clamping jaw sliding block is arranged in each sliding groove in a clamping mode. And the clamping jaw sliding block is provided with a clamping jaw. And each clamping jaw and the clamping jaw sliding block are clamped and connected with each other through a gas blowing hole.

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