CN214708532U - Continuous automatic detection equipment for assembled flexible board - Google Patents

Abstract

The application discloses continuous automated inspection equipment of equipment flexbile plate includes: the detection mechanism comprises a first conveying line, a second conveying line arranged above the first conveying line, a plurality of moving platforms positioned on the second conveying line, a detection lower die fixed on the moving platforms and a plurality of detection upper dies arranged above the second conveying line, wherein the second conveying line drives the detection lower die to sequentially pass through the detection upper dies so as to detect the flexible plate; the first conveying line is provided with a first lifting assembly positioned on the inlet side of the second conveying line and a second lifting assembly positioned on the outlet side, and the first lifting assembly is used for receiving the first conveying line and the second conveying line so as to lift the mobile platform to the inlet side of the second conveying line and lower the mobile platform to the first conveying line; the first material taking mechanism is used for placing the flexible plate on the lower detection die on the inlet side of the second conveying line; and the second material taking mechanism is used for taking out the flexible plate on the outlet side of the second conveying line. This application can realize the continuous detection of flexographic plate, improves detection efficiency.

Description

Continuous automatic detection equipment for assembled flexible board

Technical Field

The application relates to the technical field of flexible board detection, in particular to continuous automatic detection equipment for assembling flexible boards.

Background

The flexible board needs to be detected after being assembled and produced so as to ensure that the flexible board is qualified. As the functions of electronic products increase, more and more functional components are assembled on the flexible board. All functional components and parts need to be subjected to function detection respectively after the flexible board is assembled, and then the detection process after the flexible board is assembled is long, and the steps are multiple. In the prior art, a rotating disc type detection device is usually adopted, a flexible plate to be detected is manually placed in a rotating disc device, and the flexible plate is rotated by a rotating disc to be matched with a detection device for detection. The detection device comprises an upper detection die and a lower detection die, when a rotary disc type detection device is adopted, the flexible plate needs to be manually placed on the lower detection die on the rotary disc, the lower detection die is located below the upper detection die by rotating the rotary disc, the upper detection die descends and is closed to detect the flexible plate, and the flexible plate is manually taken down after detection. Because a carousel device only realizes a function of detecting, if need realize multiple function combination that detects, then need repeatedly carry on the manual work and get the turnover between putting the flexbile plate and realizing the carousel device. In the process, the labor intensity of manual operation is high, and the improvement of the production efficiency is not facilitated.

Further, although it is possible to replace manual operations with manipulators and sensors, it is still not possible to achieve a combination of successive different detection functions. And because other processes, such as film sticking, are required after the assembly of the flexible board is detected and are limited by the structure of the turntable, the automatic operation is difficult to carry out by additionally arranging equipment such as a film sticking machine on the side of the flexible board for connection. In addition, the detection devices mounted on the periphery of the turntable are limited in number due to the limitation of the size of the turntable, so that certain limitation is realized.

SUMMERY OF THE UTILITY MODEL

To the shortcomings in the technology, the application provides the continuous automatic detection equipment for the assembled flexible board, which can automatically and continuously detect the flexible board.

In order to solve the technical problem, the technical scheme adopted by the application is as follows: an assembled flexible board continuous automatic detection device, comprising: a detection mechanism comprising: the flexible board detection device comprises a first conveying line, a second conveying line arranged above the first conveying line, a plurality of moving platforms positioned on the second conveying line, a plurality of detection lower dies fixed on the moving platforms and used for installing flexible boards to be detected, and a plurality of detection upper dies arranged above the second conveying line and corresponding to the detection lower dies, wherein the second conveying line drives the moving platforms to enable the detection lower dies to sequentially pass through the detection upper dies so as to detect the flexible boards; the first conveying line is provided with a first lifting assembly positioned on the inlet side of the second conveying line and a second lifting assembly positioned on the outlet side of the second conveying line, and the first lifting assembly is used for receiving the first conveying line and the second conveying line so as to lift the mobile platform to the inlet side of the second conveying line and lower the mobile platform to the first conveying line; the first material taking mechanism is positioned on one side of the first conveying line and used for receiving the flexible plate to be detected and putting the flexible plate to be detected on the detection lower die on the inlet side of the second conveying line; and the second material taking mechanism is positioned on one side, far away from the first material taking mechanism, of the first conveying line and is used for taking out the flexible plate on the outlet side of the second conveying line.

Further, the second conveyor line includes a second carriage on which the moving platform is provided and slidable along.

Further, the second transfer chain is still including setting up the second bears the drive assembly of a frame one side, drive assembly includes that the second conveyer belt that can initiatively rotate and interval are fixed a plurality of being used for on the second conveyer belt press from both sides tightly the second fastener of platform, the second conveyer belt can drive second fastener reciprocating motion is in order to stimulate a plurality of the platform passes through in proper order go up the mould in the detection.

Further, first lifting unit includes fifth lift cylinder and connects bearing on the piston rod of fifth lift cylinder the loading board of platform, fifth lift cylinder can drive the loading board rises to the avris of second transfer chain or fall to on the first transfer chain, second lifting unit with first lifting unit structure is the same.

Further, the first conveyor line includes: the first conveying belt can rotate actively; the first bearing frame is positioned on the inner side of the first conveying belt and used for bearing a platform; the first fastening device is fixed on the first conveyor belt and used for fastening the platform; the first conveyor belt can drive the first fastening device to reciprocate between the first lifting assembly and the second lifting assembly so as to drive the platform to slide along the first bearing frame.

Further, the second transfer chain includes and is located the second bears a plurality of jacking devices of frame below, the jacking device with mould one-to-one on the detection, but the jacking device is configured into the jacking the platform, so that the decline go up the mould with the detection lower mould is closed.

Furthermore, a plurality of positioning columns are arranged on the upper detection die, and a plurality of positioning holes matched with the positioning columns are correspondingly arranged on the lower detection die.

Further, the check out test set still includes that the charging tray piles up feeding mechanism, and it includes: the limiting frame is used for accommodating the material tray containing the flexible plate; the supporting device is used for supporting the material tray and can move close to and away from the material tray and lift relative to the material tray; the lifting device is arranged at the bottom of the limiting frame and can lift relative to the limiting frame; the third conveying line is positioned below the material tray and can drive the material tray to move out of the limiting frame, and the transfer device is arranged below the third conveying line and can move and lift towards the first material taking mechanism so as to convey the material tray on the third conveying line to the first material taking mechanism; the supporting device can be far away from the lowest tray and ascends to lift other trays, and the lifting device can lower the lowest tray onto the third conveying line.

Furthermore, the first material taking mechanism comprises a placing frame for placing the material tray, two sides of the placing frame can move outwards to enable the material tray to be separated from the placing frame, and a guiding device is arranged below the placing frame and can be configured to lift relative to the placing frame to guide the material tray to fall.

Furthermore, the guiding device comprises a fourth lifting cylinder and a fourth lifting plate which is arranged on a piston rod of the fourth lifting cylinder and used for storing an empty material tray, and the fourth lifting cylinder can drive the fourth lifting plate to ascend so as to enable the material tray separated from the placing frame to fall onto the fourth lifting plate.

Compared with the prior art, the application has the beneficial effects that: this application is through setting up first transfer chain and second transfer chain, be provided with lifting unit between first transfer chain and the second transfer chain, second transfer chain both sides set up first feeding agencies and second feeding agencies respectively, the support plate on the second transfer chain can be driven and the circulation flows back to the second transfer chain by first transfer chain and lifting unit, first feeding agencies and second feeding agencies can be respectively with the flexonics board that waits to detect put into the support plate and take out the support plate with the flexonics board after the test to realize the continuous detection of flexonics board, improve detection efficiency.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts. Wherein:

fig. 1 is the overall structure schematic diagram of the automatic detection device of the present invention.

Fig. 2 is a schematic structural diagram of the feeding mechanism and the first material taking mechanism stacked on the middle tray of the present invention.

Fig. 3 is a partial enlarged view of fig. 2 at a.

Fig. 4 is a partial enlarged view of fig. 2 at B.

Fig. 5 is a schematic structural view of the material tray stacking and feeding mechanism in another direction according to the present invention.

Fig. 6 is a schematic structural diagram of the middle detecting mechanism and the second material taking mechanism of the present invention.

Fig. 7 is a schematic top view of the second conveyor line according to the present invention.

In the figure:

100. a material tray stacking and feeding mechanism; 10. a material tray; 11. a limiting frame; 12. a support device; 121. A first lifting cylinder; 122. a first lifter plate; 123. a support cylinder; 124. a support block; 13. A lifting device; 131. a second lifting cylinder; 132. a second lifter plate; 14. a third conveyor line; 15. a transfer device; 151. a first linear module; 152. a movable frame; 153. a third lifting cylinder; 154. a third lifter plate; 16. a first limit component; 161. a first limit cylinder; 162. a first stopper; 200. a detection mechanism; 21. a first conveyor line; 211. a first conveyor belt; 212. a first fastening device; 213. a first carrier; 22. a second conveyor line; 221. a second carrier; 222. a drive assembly; 2221. a second conveyor belt; 2222. a second fastening device; 223. a jacking device; 231. detecting the upper die; 232. detecting the lower die; 24. a mobile platform; 25. A first lifting assembly; 251. a fifth lifting cylinder; 252. a carrier plate; 26. a second lifting assembly; 300. a first material taking mechanism; 31. a first manipulator; 32. a placement frame; 33. a second limiting component; 331. a second limit cylinder; 332. a second limiting block; 34. a guide device; 341. a fourth lifting cylinder; 342. a fourth lifter plate; 35. a second manipulator; 36. a positioning table; 400. a second material taking mechanism; 41. a third manipulator; 500. a transfer table; 51. a second linear module; 52. A mobile station; 600. and (5) an action platform.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present application more comprehensible, embodiments accompanying the present application are described in detail below with reference to the accompanying drawings. It is to be understood that the specific embodiments described herein are merely illustrative of the application and are not limiting of the application. It should be further noted that, for the convenience of description, only some of the structures related to the present application are shown in the drawings, not all of the structures. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The terms "comprising" and "having," as well as any variations thereof, in this application are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

As shown in fig. 1, the automatic continuous inspection equipment for assembled flexible boards according to a preferred embodiment of the present invention includes: the material tray stacking and feeding mechanism 100 is used for stacking material trays 10 provided with flexible plates and moving out the material tray 10 at the bottommost layer; detection mechanism 200, comprising: the flexible plate detection device comprises a first conveying line 21, a second conveying line 22 arranged above the first conveying line 21, a plurality of moving platforms 24 positioned on the second conveying line 22, a plurality of detection lower dies 232 which are fixed on the moving platforms 24 and are provided with flexible plates to be detected, and a plurality of detection upper dies 231 which are arranged above the second conveying line 22 and correspond to the detection lower dies 232; the first conveying line 21 is used for receiving the moving platform 24 on the outlet side of the second conveying line 22, driving the moving platform 24 to move towards the inlet side of the second conveying line 22 and sending the moving platform 24 into the second conveying line 22, and the second conveying line 22 drives the moving platform 24 provided with the detection lower die 232 to pass through the detection upper die 231 in sequence so as to detect the flexible board; the first material taking mechanism 300 is positioned between the tray stacking and feeding mechanism 100 and the first conveying line 21, and is used for receiving the trays 10 moved out of the tray stacking and feeding mechanism 100 and placing the flexible plates on the trays 10 on the detection lower die 232 on the inlet side of the second conveying line 22; and a second material taking mechanism 400, located on the side of the first conveying line 21 away from the first material taking mechanism 300, for taking out the flexible board on the outlet side of the second conveying line 22.

Referring to fig. 1 to 5, the tray stacking and feeding mechanism 100 includes a limiting frame 11, a supporting device 12, a lifting device 13, a third conveying line 14, and a transfer device 15. The limiting frame 11 is used for accommodating the stacked charging trays 10; the supporting device 12 is arranged at the side of the limiting frame 11 and used for supporting the material tray 10, and can move towards and away from the material tray 10 and lift relative to the material tray; the lifting device 13 is arranged at the bottom of the limiting frame 11 and can lift relative to the limiting frame 11; the third conveying line 14 is positioned below the material tray 10 and can drive the material tray 10 to move out of the limit frame 11; the transfer device 15 is disposed below the third conveyor line 14 and is movable and liftable toward the first taking mechanism 300. When the tray stacking and feeding mechanism 100 works, the lifting device 13 is lifted upwards to support the trays 10, the supporting device 12 can be far away from the lowest tray 10 and lifted to lift other trays 10, the lifting device 13 is lowered to drive the lowest tray 10 to be placed on the third conveying line 14, and the third conveying line 14 can move the trays 10 out of the limiting frame 11 and convey the trays into the first material taking mechanism 300 through the conveying device 15.

Specifically, a groove (not shown) is formed on the side of the tray 10, and when the trays 10 are stacked, a gap exists between the tray 10 and the tray 10. The supporting device 12 includes a first elevating cylinder 121, a first elevating plate 122 installed on a piston rod of the first elevating cylinder 121, a supporting cylinder 123 installed on the first elevating plate 122, and a supporting block 124 installed on a piston rod of the supporting cylinder 123. Preferably, each first lifting plate 122 is provided with two supporting cylinders 123, and the supporting cylinders 123 are respectively located at two ends of one side of the tray 10 and can extend and retract towards the tray 10. Initially, the support cylinder 123 is located at the lowest tray 10, and the bottom of the lowest tray 10 is supported by the support block 124. In this embodiment, the supporting devices 12 are two in number and are oppositely arranged to support both sides of the tray 10.

The lifting device 13 comprises a second lifting cylinder 131 and a second lifting plate 132 installed on a piston rod of the second lifting cylinder 131, and the second lifting cylinder 131 can drive the second lifting plate 132 to lift and lower the tray 10 to the third conveying line 14.

The third conveying line 14 may specifically adopt a belt conveying or a roller conveying, which is common knowledge in the art and will not be described herein. The end of the third conveying line 14 is provided with a first limiting assembly 16 for limiting the tray 10 to move out of the third conveying line 14, the first limiting assembly 16 comprises a first limiting cylinder 161 and a first limiting block 162 installed on a piston rod of the first limiting cylinder 161, and the first limiting cylinder 161 can drive the first limiting block 162 to descend to block the tray 10 and ascend to enable the tray 10 to leave the third conveying line 14.

The transfer device 15 includes a first linear block 151 located below the third conveyor line 14, a moving frame 152 provided on the first linear block 151, a third lift cylinder 153 provided on the moving frame 152, and a third lift plate 154 attached to a piston rod of the third lift cylinder 153. The third lifting cylinder 153 can drive the third lifting plate 154 to lift the tray 10 on the third conveying line 14 upwards, and the first linear module 151 can drive the moving frame 152 to move to the first material taking mechanism 300, so as to feed the tray 10 into the first material taking mechanism 300.

The first material taking mechanism 300 comprises a first manipulator 31 and a placing frame 32 which is positioned below the first manipulator 31 and is used for placing the material tray 10, the first manipulator 31 is used for taking out the flexible plate in the material tray 10, and two sides of the placing frame 32 can move outwards to enable the material tray 10 which is taken out of the flexible plate to be separated from the placing frame 32. The rack 32 can be driven by an air cylinder or a screw rod.

Preferably, in order to ensure the stability of the tray 10 when the first manipulator 31 grasps the flexible board, the placing frame 32 is provided with a second limiting component 33, the second limiting component 33 comprises a second limiting cylinder 331 and a second limiting block 332 installed on a piston rod of the second limiting cylinder 331, and the second limiting cylinder 331 can drive the second limiting block 332 to move downwards to press the tray 10.

Preferably, a guiding device 34 is disposed below the rack 32, and the guiding device 34 is configured to be lifted and lowered relative to the rack 32 to guide the tray 10 to fall. The guiding device 34 includes a fourth lifting cylinder 341 and a fourth lifting plate 342 mounted on a piston rod of the fourth lifting cylinder 341 for storing the empty tray 10, and the fourth lifting cylinder 341 can drive the fourth lifting plate 342 to ascend so that the tray 10 separated from the rack 32 falls onto the fourth lifting plate 342.

In addition, the first material taking mechanism 300 further includes a second manipulator 35 and a positioning table 36 disposed below the second manipulator 35, the positioning table 36 is located on one side of the placement frame 32, the first manipulator 31 transfers the flexible board on the tray 10 to the positioning table 36 for fine positioning, and the second manipulator 35 scans the two-dimensional code attached to the flexible board and transfers the two-dimensional code to the moving platform 24 of the first conveying line 21. Preferably, the manipulator can be replaced by an XY axis translation mechanism, and a sucker for sucking the flexible plate or other pick-and-place mechanisms can be arranged on the translation mechanism.

Referring to fig. 1, 6 and 7, the second conveyor line 22 includes a second carriage 221, and the moving platform 24 is disposed on the second carriage 221 and slidable along the second carriage 221. The second transfer line 22 further includes a driving unit 222 disposed at one side of the second carriage 221, and the driving unit 222 is configured to reciprocate along the second carriage 221 and drag the moving platform 24 sequentially past the plurality of inspection upper molds 231.

The second transfer line 22 further includes a driving unit 222 disposed at one side of the second carriage 221, and the driving unit 222 is configured to reciprocate along the second carriage 221 and drag the moving platform 24 sequentially past the plurality of inspection upper molds 231.

The driving assembly 222 includes a second conveying belt 2221 capable of actively rotating and a plurality of second fastening devices 2222 fixed to the second conveying belt 2221 at intervals, and the second fastening devices 2222 are used for clamping the moving platform 24 lifted to the second conveying line 22, so as to pull the moving platform 24 to move towards the upper detection mold 231 under the driving of the second conveying belt 2221. In this embodiment, the second fastening device 2222 may specifically adopt a clamping cylinder to clamp or unclamp the moving platform 24.

The number of the second fastening devices 2222 is one more than the number of the detecting upper molds 231, so that the second fastening devices 2222 located at the end of the second conveying belt 2221 correspond to the first lifting unit 25 or the second lifting unit 26, thereby drawing the moving platform 24 on the first lifting unit 25 into the second carriage 221 or drawing the moving platform 24 after detecting the flexible board into the second lifting unit 26.

The second conveying line 22 further includes a plurality of jacking devices 223 located below the second carriage 221, the jacking devices 223 correspond to the upper detection dies 231 one by one, and the jacking devices 223 are configured to jack the movable platform 24 so as to close the lower detection dies 231 and the upper detection dies 232 which are lowered.

The jacking device 223 comprises a jacking cylinder 2231 and a jacking plate 2232 connected to a piston rod of the jacking cylinder 2231, and the jacking cylinder 2231 can drive the jacking plate 2232 to ascend so as to jack the movable platform 24 located below the detection upper die 231. In this process, the inspection upper die 231 is lowered to be engaged with the inspection upper die 231, thereby inspecting the flexible board.

Preferably, the upper detection die 231 is provided with a plurality of positioning posts 2311, and the lower detection die 232 is correspondingly provided with a plurality of positioning holes 2321 matched with the positioning posts 2311, so that accurate positioning of the upper detection die 231 and the lower detection die 232 after die assembly is realized.

The first conveying line 21 is provided with a first lifting assembly 25 positioned on the inlet side of the second conveying line 22 and a second lifting assembly 26 positioned on the outlet side of the second conveying line 22, and the first lifting assembly 25 and the second lifting assembly are used for receiving the first conveying line 21 and the second conveying line 22 so as to lift the moving platform 24 to the inlet side of the second conveying line 22 and lower the moving platform 24 to the first conveying line 21.

Specifically, the first lifting assembly 25 includes a fifth lifting cylinder 251 and a bearing plate 252 connected to a piston rod of the fifth lifting cylinder 251 and used for bearing the moving platform 24, and the fifth lifting cylinder 251 can drive the bearing plate 252 to be lifted to the side of the second conveying line 22. The second lifting assembly 26 has the same structure as the first lifting assembly 25, and the structure thereof is not described herein again. In operation, the second robot 35 is used to move the flexible board into the lower inspection mold 232 on the carrier plate 252. In the present embodiment, the carrier plate 252 may receive the flexible board when located at the first conveying line 21 or when lifted to the second conveying line 22, and the present application is not particularly limited thereto.

The first conveyor line 21 comprises a first actively rotatable conveyor belt 211 and a first fastening device 212 fixed to the first conveyor belt 211 for fastening the moving platform 24. The first fastening device 212 may specifically employ a clamping cylinder (not shown) to clamp and unclamp the mobile platform 24. Preferably, the first conveyor line 21 further includes a first carriage 213 located inside the first conveyor belt 211 for carrying the movable platform 24, and the movable platform 24 is placed on the first carriage 213 and can slide along the first carriage 213. The first conveyor belt 211 can drive the first fastening device 212 to reciprocate between the first lifting assembly 25 and the second lifting assembly 26 to drive the moving platform 24 to slide along the first loading frame 213.

The second material taking mechanism 400 comprises a third manipulator 41 capable of actively moving, and the third manipulator 41 is positioned above the second lifting assembly 26 to take the detected flexible board out of the tray 10.

Referring to fig. 1, the inspection apparatus further includes a transfer table 500 provided at a side of the second material taking mechanism 400 and a motion platform 600 provided at a side of the transfer table 500. The transfer table 500 is configured to receive the flexible board taken out by the third manipulator 41, scan the two-dimensional code again, and record the detection information into the production system through scanning twice. To include the information. Preferably, a waste recycling frame (not shown) may be provided near the third robot 41 according to the recorded information to place the defective flexible board in the waste recycling frame. In this embodiment, the motion platform 600 is specifically a film laminator, the transfer platform 500 includes a second linear module 51 and a moving stage 52 disposed on the second linear module 51 for placing and positioning the flexible board, and the second linear module 51 can drive the moving stage 52 to move to the film laminator for film lamination. Indeed, in other embodiments, other motion platforms may be accessible behind the mobile station 52 as needed for production.

The use method of the continuous automatic detection equipment for the assembled flexible plate comprises the following steps: s1, the tray stacking and feeding mechanism 100 transfers the tray 10 to the first material taking mechanism 300;

s2, the first conveyor line 21 transfers the movable platform 24 with the empty detection lower die 232 fixed thereon to the first lifting assembly 25, and the first lifting assembly 25 lifts the movable platform 24 to the inlet side of the second conveyor line 22;

s3, the first material taking mechanism 300 transfers the flexible board to be detected in the tray 10 to the positioning table 36 for accurate positioning and then transfers the flexible board to the detection lower die 232;

s4, the driving assembly 222 pulls the plurality of moving platforms 24 to move synchronously along the second loading frame 221, each time the moving platform 24 is pulled, the moving platform 24 reaches below one detection upper die 231, the detection upper die 231 descends, the detection lower die 232 ascends, and the detection upper die 231 and the detection lower die 232 are closed to detect the flexible board, in the process, the moving platform 24 on the first lifting assembly 25 is pulled to be below the detection upper die 231 at the head end position, and the moving platform 24 below the detection upper die 231 at the tail end position is pulled to be above the second lifting assembly 26;

s5, the second material taking mechanism 400 takes out the moving platform 24 from the detected flexible board, and the second lifting assembly 26 lowers the empty moving platform 24 to the first conveying line 21 and transfers it to the first lifting assembly 25 again, so as to realize continuous detection.

To sum up, this application is provided with lifting unit between first transfer chain and the second transfer chain through setting up first transfer chain and second transfer chain, second transfer chain both sides set up first feeding agencies and second feeding agencies respectively, the support plate on the second transfer chain can be driven and circulate back to the second transfer chain by first transfer chain and lifting unit, first feeding agencies and second feeding agencies can put into the support plate and take out the support plate with the flexbile plate after the test with the flexbile plate that waits to detect respectively to realize the continuous detection of flexbile plate, improve detection efficiency.

The above description is only for the purpose of illustrating embodiments of the present invention and is not intended to limit the scope of the present invention, and all modifications, equivalents, and equivalent structures or equivalent processes that can be used directly or indirectly in other related fields of technology shall be encompassed by the present invention.

Claims (10)

1. The utility model provides an equipment flexible sheet continuous automatic check out test set which characterized in that includes:

detection mechanism (200) comprising: the flexible plate detection device comprises a first conveying line (21), a second conveying line (22) arranged above the first conveying line (21), a plurality of moving platforms (24) located on the second conveying line (22), a plurality of detection lower dies (232) fixed on the moving platforms (24) and used for installing flexible plates to be detected, and a plurality of detection upper dies (231) arranged above the second conveying line (22) and corresponding to the detection lower dies (232), wherein the second conveying line (22) drives the moving platforms (24) to enable the detection lower dies (232) to sequentially pass through the detection upper dies (231) so as to detect the flexible plates;

wherein the first conveying line (21) is provided with a first lifting assembly (25) positioned at the inlet side of the second conveying line (22) and a second lifting assembly (26) positioned at the outlet side of the second conveying line (22), and the first lifting assembly is used for receiving the first conveying line (21) and the second conveying line (22) so as to lift the moving platform (24) to the inlet side of the second conveying line (22) and lower the moving platform (24) to the first conveying line (21);

the first material taking mechanism (300) is positioned on one side of the first conveying line (21) and used for receiving the flexible board to be detected and putting the flexible board to be detected on the detection lower die (232) on the inlet side of the second conveying line (22); and

and the second material taking mechanism (400) is positioned on one side, away from the first material taking mechanism (300), of the first conveying line (21) and used for taking out the flexible plate on the outlet side of the second conveying line (22).

2. The apparatus for continuously and automatically inspecting assembled flexible boards according to claim 1, wherein the second conveyor line (22) comprises a second carriage (221), and the moving platform (24) is provided on the second carriage (221) and is slidable along the second carriage (221).

3. The continuous automatic detection equipment for the assembled flexible printed circuit board according to claim 2, wherein the second conveyor line (22) further comprises a driving assembly (222) disposed on one side of the second loading frame (221), the driving assembly (222) comprises a second conveyor belt (2221) capable of actively rotating and a plurality of second fastening devices (2222) fixed on the second conveyor belt (2221) at intervals and used for clamping the moving platforms (24), and the second conveyor belt (2221) can drive the second fastening devices (2222) to reciprocate so as to pull the plurality of moving platforms (24) to pass through the upper detection die (231) in sequence.

4. The continuous automatic detection equipment for the assembled flexible boards according to claim 1, wherein the first lifting assembly (25) comprises a fifth lifting cylinder (251) and a bearing plate (252) connected to a piston rod of the fifth lifting cylinder (251) and carrying the moving platform (24), the fifth lifting cylinder (251) can drive the bearing plate (252) to be lifted to the side of the second conveying line (22) or to be lowered onto the first conveying line (21), and the second lifting assembly (26) is identical to the first lifting assembly (25).

5. The continuous automatic inspection apparatus of assembled flexible boards according to claim 1, wherein the first conveyor line (21) comprises:

a first conveyor belt (211) which can actively rotate;

a first carriage (213) inside the first conveyor belt (211) for carrying a moving platform (24); and

-first fastening means (212) fixed on said first conveyor belt (211) for fastening said mobile platform (24);

wherein the first conveyor belt (211) can drive the first fastening device (212) to reciprocate between the first lifting assembly (25) and the second lifting assembly (26) so as to drive the moving platform (24) to slide along the first bearing frame (213).

6. The continuous automatic inspection apparatus for assembled flexible boards according to claim 2, wherein the second conveyor line (22) comprises a plurality of lifting devices (223) located below the second carriage (221), the lifting devices (223) correspond to the inspection upper dies (231) in a one-to-one manner, and the lifting devices (223) are configured to lift the moving platform (24) so as to close the inspection upper dies (231) and the inspection lower dies (232) which are lowered.

7. The continuous automatic detection equipment for the assembled flexible plates as claimed in claim 1, wherein a plurality of positioning columns (2311) are arranged on the upper detection die (231), and a plurality of positioning holes (2321) matched with the positioning columns (2311) are correspondingly arranged on the lower detection die (232).

8. The continuous automatic detection equipment of assembled flexible plates according to claim 1, characterized in that it further comprises a tray stacking and feeding mechanism (100) comprising:

the limiting frame (11) is used for accommodating the material tray (10) accommodating the flexible plate;

the supporting device (12) is used for supporting the material tray (10) and can move close to and away from the material tray (10) and lift relative to the material tray;

the lifting device (13) is arranged at the bottom of the limiting frame (11) and can lift relative to the limiting frame (11);

a third conveying line (14) which is positioned below the material tray (10) and can drive the material tray (10) to move out of the limit frame (11), and

the transfer device (15) is arranged below the third conveying line (14) and can move and lift towards the first material taking mechanism (300) so as to convey the material tray (10) on the third conveying line (14) to the first material taking mechanism (300);

the supporting device (12) can be far away from the lowest tray (10) and ascends to lift other trays (10), and the lifting device (13) can lower the lowest tray (10) onto the third conveying line (14).

9. The continuous automatic detection equipment for the assembled flexible plates is characterized in that the first material taking mechanism (300) comprises a placing frame (32) for placing the material tray (10), two sides of the placing frame (32) can move outwards to enable the material tray (10) to be separated from the placing frame (32), a guide device (34) is arranged below the placing frame (32), and the guide device (34) is configured to be capable of lifting relative to the placing frame (32) to guide the material tray (10) to fall.

10. The apparatus for continuously and automatically detecting assembled flexible plates according to claim 9, wherein the guiding device (34) comprises a fourth lifting cylinder (341) and a fourth lifting plate (342) installed on a piston rod of the fourth lifting cylinder (341) for storing empty trays (10), the fourth lifting cylinder (341) can drive the fourth lifting plate (342) to ascend so that the trays (10) separated from the placing rack (32) fall onto the fourth lifting plate (342).

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