CN211225299U - FPC soft board center positioning machine - Google Patents

Abstract

The utility model discloses a FPC soft board center positioning machine for carry FPC soft board, which comprises a frame, conveying mechanism, drive mechanism, cross cab apron and clapper, conveying mechanism sets up in the frame along the horizontal direction, FPC soft board is placed on conveying mechanism, conveying mechanism includes first conveying component, second conveying component, first conveying component links to each other end to end with second conveying component, drive mechanism includes first drive assembly and second drive assembly, first drive assembly orders FPC soft board to move on first conveying component, second drive assembly orders FPC soft board to move on second conveying component, FPC soft board is carried to second conveying component input by first conveying component output; the transition plate is arranged on the second conveying component, and the two clapboards simultaneously move inwards or outwards along the left-right direction above the second conveying component. The FPC soft board center positioning machine can prevent the FPC soft board from falling in the conveying process and reduce the rejection rate of the FPC soft board.

Description

FPC soft board center positioning machine

Technical Field

The utility model relates to a mechanical equipment's technical field, in particular to FPC soft board center location machine.

Background

The FPC soft board center positioning machine is used for conveying FPC soft boards. The existing equipment is mainly used for conveying in a conveying wheel mode, and a clapper positioning structure is required to be added in the existing equipment to increase the range of the equipment capable of producing products. When the clapper positioning structure is not arranged, a conveying belt or other conveying structures without gaps can be adopted; but just can not adopt monoblock conveyer belt when using clapper location structure, have the clearance like this between the delivery wheel, the FPC soft board of production among the prior art is more and more thin, and the FPC soft board can drop from the clearance between the delivery wheel.

Therefore, the FPC center positioning machine for preventing the FPC from falling off is provided.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides a FPC soft board center location machine has the increase and can produce the product scope, prevent that FPC soft board from dropping, reducing the advantage of disability rate.

In order to achieve the above object, the utility model provides a FPC soft board center positioning machine for carry FPC soft board, including frame, conveying mechanism, drive mechanism, cross cab apron and clapper, conveying mechanism set up in the frame along the horizontal direction, the FPC soft board is placed on conveying mechanism, conveying mechanism includes first conveying component, second conveying component, first conveying component links to each other end to end with the second conveying component, drive mechanism includes first drive component and second drive component, the first drive component orders the FPC soft board to move on the first conveying component, the second drive component orders the FPC soft board to move on the second conveying component, the FPC soft board is carried to the second conveying component input by the first conveying component output; the transition plate is arranged on the second conveying assembly, and the two clapboards simultaneously move inwards or outwards along the left-right direction above the second conveying assembly.

Preferably, the first conveying assembly comprises a first rotating shaft, the first rotating shaft is perpendicular to the moving direction of the FPC flexible printed circuit board, each first rotating shaft is evenly sleeved with a plurality of first conveying wheels, and every two first conveying wheels are arranged on the first rotating shaft in a staggered mode.

Preferably, the second conveying assembly comprises a second rotating shaft and a plurality of second rotating shafts perpendicular to the moving direction of the FPC soft board, each second rotating shaft is sequentially sleeved with a plurality of second conveying wheels, the second conveying wheels are arranged on the second rotating shafts in sequence, a first interval is formed between the second conveying wheels, and the transition plate is arranged in the first interval.

Preferably, a second interval is arranged between a plurality of first conveying wheels on the first rotating shaft closest to the second conveying assembly, and the front end of the transition plate extends to the second interval and is positioned above the first rotating shaft.

Preferably, the FPC flexible printed circuit board center positioning machine further includes a clapper pushing mechanism for pushing the clapper to move, the clapper pushing mechanism is located below the second conveying assembly, the clapper pushing mechanism includes a first motor, a first belt, a driving wheel, a driven wheel, a guide rod, a first fixing member, and a second fixing member, the first motor is arranged on the frame along the vertical direction, the driving wheel is located above the first motor and connected to an output end of the first motor, the driving wheel is connected to the driven wheel through the first belt, the driving wheel and the driven wheel are respectively located below the corresponding clappers, the guide rod is arranged on the frame along the second rotation axis direction, the first fixing member and the second fixing member are slidably arranged on the guide rail, and the first fixing member is connected to one of the clappers, the second fixing piece is connected to the other clapper, and the first fixing piece and the second fixing piece are fixed to two sides of the first belt respectively.

Preferably, the first transmission assembly comprises a first connecting rod, the second transmission assembly comprises a second connecting rod, the first connecting rod is perpendicular to the first rotating shaft, and the second connecting rod is perpendicular to the second rotating shaft; the two first connecting rods are positioned at two ends of the plurality of first rotating shafts, and the two second connecting rods are positioned at two ends of the second rotating shafts.

Preferably, the first transmission assembly further comprises a second motor, a second belt, a third belt, a fourth belt conveyor and a gear box, the second motor is arranged right below one of the first connecting rods along the horizontal direction, and the gear box is arranged right below the other first connecting rod; the second belt and the fourth belt are arranged along the vertical direction, and the third belt is arranged along the horizontal direction; one end of the second belt is sleeved on the corresponding first connecting rod, and the other end of the second belt is sleeved on the output end of the second motor; one end of the third belt is sleeved at the output end of the second motor, and the other end of the third belt is sleeved at the input end of the gear box; one end of the fourth belt is sleeved on the output end of the gear box, and the fourth belt is sleeved on the corresponding first connecting rod.

Preferably, the first transmission assembly further comprises a plurality of bevel gears, each bevel gear comprises a first gear and a second gear, the axes of the first gears are perpendicular to the axes of the second gears, the first gears are meshed with the second gears, the plurality of first gears are sleeved on the first connecting rod or the second connecting rod, and the second gears are connected to two ends of the first rotating shaft or the second rotating shaft.

Preferably, first transmission assembly still includes the multiple gear unit, the multiple gear unit includes input gear, transition gear and output gear, input gear the transition gear reaches output gear meshes in proper order, the input gear cover is located on the first axis of rotation, the transition gear with first axis of rotation length direction is the pivot joint in the frame, the output gear cover is located adjacently first axis of rotation both ends.

Preferably, the FPC flexible printed circuit center positioning machine further includes a first partition plate, a second partition plate, and a fixed baffle, the first partition plate is perpendicular to the first rotating shaft and located in the middle of the first rotating shaft, and the second partition plate is perpendicular to the second rotating shaft and located in the middle of the second rotating shaft; the fixed baffle is positioned at the output end of the transition plate.

Compared with the prior art, the utility model discloses following beneficial effect has: the utility model discloses a FPC soft board center positioning machine accomplishes the transportation process of whole FPC soft board through first conveying component, second conveying component, and the bat board can inside outwards remove the multiplicable product size scope of can producing, can fix a position the FPC soft board in transportation process through the bat board, and prevents through the cab apron that the FPC soft board from dropping from the delivery wheel clearance in transportation process, reduces the disability rate of FPC soft board production process.

Drawings

Fig. 1 is a first perspective view of a FPC flexible printed circuit board center positioning machine according to an embodiment of the present invention.

Fig. 2 is a second perspective view of the FPC flexible printed circuit board center positioning machine according to the embodiment of the present invention.

Fig. 3 is an enlarged view of a portion a of fig. 1.

Fig. 4 is an enlarged view of a portion B of fig. 1.

Fig. 5 is an enlarged view of a portion C in fig. 2.

Fig. 6 is a perspective view of the clapper pushing mechanism according to the embodiment of the present invention.

Detailed Description

In order to make the technical means, creation features, achievement purposes and functions of the present invention easy to understand, the present invention is further described below with reference to the following embodiments.

The utility model discloses a FPC soft board center positioning machine 100 is used for carrying FPC (flexible Printed circuit) flexible circuit board soft board, and this FPC soft board center positioning machine 100 avoids the FPC soft board to drop in transportation process through increasing cab apron 40.

Fig. 1-6 are different views of the FPC flexible printed circuit board centering machine 100 according to the embodiment of the present invention, and the structure of the FPC flexible printed circuit board centering machine 100 will be described in detail with reference to the accompanying drawings:

referring to fig. 1 and 2, the FPC flexible printed circuit board centering device 100 of the present embodiment includes a frame 10 and a conveying mechanism (not shown), wherein the conveying mechanism is disposed on the frame 10 along a horizontal direction, the FPC flexible printed circuit board is placed on the conveying mechanism, the conveying mechanism includes a first conveying assembly 21 and a second conveying assembly 22, and the first conveying assembly 21 and the second conveying assembly 22 are connected end to end.

The first conveying assembly 21 is used for straight conveying of the FPC flexible printed circuit board, the first conveying assembly 21 has various forms, and the first conveying assembly 21 can be conveying belt conveying or conveying wheel conveying. In the present embodiment, a conveying wheel manner is adopted, please further refer to fig. 4, the first conveying assembly 21 of the present embodiment includes a plurality of first rotating shafts (not shown in the figure), the plurality of first rotating shafts are disposed along a direction perpendicular to a moving direction of the FPC flexible printed circuit board, each first rotating shaft is uniformly sleeved with a plurality of first conveying wheels 211, and the first conveying wheels 211 on two adjacent first rotating shafts are disposed in a staggered manner. The FPC soft board is placed on the upper surface of the first conveying wheel 211 in the conveying process, the gap between the two first rotating shafts can be filled through the staggered arrangement of the first conveying wheel 211, and the FPC soft board conveyed on the first conveying assembly 21 conveyed in the straight direction cannot fall off.

After the flexible printed circuit board passes through the first conveying assembly 21, the flexible printed circuit board is conveyed from the output end of the first conveying assembly 21 to the input end of the second conveying assembly 22. The second conveying assembly 22 is used for the straight conveying and the transverse movement of the FPC soft board, and the transverse movement ensures the accurate positioning of the FPC soft board.

Referring to fig. 1, the FPC flexible printed circuit board centering machine 100 of the present embodiment further includes a transition plate 40 and two flap plates 50, wherein the transition plate 40 is disposed on the second conveying assembly 22, and the two flap plates 50 simultaneously move inwards or outwards in the left-right direction above the second conveying assembly 22. In this embodiment, the position of the FPC flexible printed circuit board is located by the pushing action of the flap 50, a flap pushing structure 60 for pushing the flap 50 to move needs to be arranged in the range of the second conveying assembly 22, and the FPC flexible printed circuit board easily drops between the gaps of the second conveying wheels 221 on the two adjacent second rotating shafts.

The structure of the second conveyor assembly 22 is described in detail below:

referring to fig. 1, the second conveying assembly 22 of the present embodiment includes a plurality of second rotating shafts (not shown), the plurality of second rotating shafts are disposed along a direction perpendicular to the moving direction of the FPC flexible printed circuit, and each of the plurality of second rotating shafts is sequentially sleeved with a plurality of second conveying wheels 221. Referring to fig. 4, a first space 222 is provided between the second conveying wheels 221 on the same second rotation axis, the transition plate 40 is disposed in the first space 222, the length of a single second conveying wheel 221 is smaller than that of a single FPC flexible printed circuit by the arrangement of the transition plate 40, and the transition plate 40 is disposed in the middle of the FPC flexible printed circuit, so that the FPC flexible printed circuit can be prevented from falling.

Further, a second gap 212 is provided between a plurality of first conveying wheels 211 on the first rotating shaft closest to the second conveying assembly 22, and the front end of the transition plate 40 extends to between the second gaps 212 and above the first rotating shaft. When the FPC flexible printed circuit reaches the output end of the first conveying assembly 21, the FPC flexible printed circuit can be smoothly conveyed onto the second conveying assembly 22 through the front end of the transition plate 40, so as to further prevent the FPC flexible printed circuit from falling from the gap between the first conveying wheel 211 and the second conveying wheel 221 at the junction of the first conveying assembly 21 and the second conveying assembly 22.

The FPC soft board comprises straight conveying and transverse pushing in the second conveying assembly 22, the FPC soft board center positioning machine 100 further comprises a clapper pushing structure 60 for pushing the clappers 50 to move, the clapper pushing structure 60 is located below the second conveying assembly 22, and the clappers 50 moving transversely push and position the FPC soft board.

The flap pushing structure 60 is described in detail below:

referring to fig. 6, the flap pushing structure 60 of the present embodiment includes a first motor 61, a first belt 62, a driving wheel 63, a driven wheel 64, a guide rod 65, a first fixing member 66, and a second fixing member 67, where the first motor 61 is disposed on the frame 10 along the vertical direction, the driving wheel 63 is disposed above the first motor 61 and connected to an output end of the first motor 61, the driving wheel 63 and the driven wheel 64 are respectively disposed below the corresponding flaps 50, the driving wheel 63 is connected to the driven wheel 64 through the first belt 62, the guide rod 65 is disposed on the frame 10 along the second rotation axis direction, the first fixing member 66 and the second fixing member 67 are slidably disposed on the guide rail, the first fixing member 66 is connected to one of the flaps 50, the second fixing member 67 is connected to the other flap 50, and the first fixing member 66 and the second fixing member 67 are respectively fixed to two sides of the first belt. Then, the first motor 61 drives the first belt 62 to rotate in a reciprocating manner, and the first fixing member 66 and the second fixing member 67 on the first belt 62 move along with the first belt 62, so as to drive the corresponding clappers 50 to move inwards or outwards in the left-right direction at the same time.

Further, the FPC flexible printed circuit center positioning machine 100 of this embodiment further includes a transmission mechanism 30, the transmission mechanism 30 includes a first transmission assembly 31 and a second transmission assembly 32, the first transmission assembly 31 drives the FPC flexible printed circuit to move on the first conveying assembly 21, and the second transmission assembly 32 drives the FPC flexible printed circuit to move on the second conveying assembly 22. Referring to fig. 1, the first transmission assembly 31 of the present embodiment includes a first connecting rod 311, the second transmission assembly includes a second connecting rod 321, the first connecting rod 311 is perpendicular to the first rotating shaft, and the second connecting rod 321 is perpendicular to the second rotating shaft; the two first connecting rods 311 are located at both ends of the plurality of first rotating shafts, and the two second connecting rods 321 are located at both ends of the second rotating shafts. Then, the first link 311 rotates to drive the first rotating shaft to rotate, and the second link 321 rotates to drive the second rotating shaft to rotate.

The first transmission assembly 31 and the second transmission assembly 32 have the same structure, and the following description will only take the structure of the first transmission assembly 31 as an example:

furthermore, referring to fig. 3 and fig. 5, the first transmission assembly 31 further includes a second motor 312, a second belt 313, a third belt 314, a fourth belt 315, and a gear box 316, wherein the second motor 312 is disposed right below one of the first connecting rods 311 along the horizontal direction, and the gear box 316 is disposed right below the other first connecting rod 311; the second belt 313 and the fourth belt 315 are both arranged along the vertical direction, and the third belt 314 is arranged along the horizontal direction; one end of the second belt 313 is sleeved on the corresponding first connecting rod 311, and the other end of the second belt 313 is sleeved on the output end of the second motor 312; one end of the third belt 314 is sleeved at the output end of the second motor 312, and the other end of the third belt 314 is sleeved at the input end of the gear box 316; one end of the fourth belt 315 is sleeved on the output end of the gear box 316, and the fourth belt 315 is sleeved on the corresponding first connecting rod 311.

When the second motor 312 works, the second motor 312 drives the second belt 313 to rotate, and the second belt 313 drives the first connecting rod 311 connected to the other end to rotate; the second motor 312 electrically drives the third belt 314 connected thereto to rotate, the third belt 314 drives the fourth belt 315 to rotate through the gear box 316, and the fourth belt 315 drives the first connecting rod 311 connected to the other end to rotate.

The first transmission assembly 31 further includes a plurality of bevel gears 317, the bevel gears 317 include a first gear 317a and a second gear 317b, an axis of the first gear 317a is perpendicular to an axis of the second gear 317b, the first gear 317a is engaged with the second gear 317b, the plurality of first gears 317a are sleeved on the first connecting rod 311, and the second gear 317b is connected to two ends of the first rotating shaft. Then, when the first connecting rods 311 at both ends of the first rotating shaft rotate, the first connecting rods 311 drive the first gear 317a to rotate, and the first gear 317a drives the second gear 317b to rotate around the first rotating shaft, so as to drive the first rotating shaft to rotate; the first rotating shaft then drives the first conveying wheel 211 fixed thereon to rotate, so that the FPC flexible printed circuit board on the first conveying wheel 211 moves forward.

Further, the bevel gear 317 is generally directly connected to the first rotating shaft, so that the first rotating shaft can rotate. However, when other components are disposed at positions where the bevel gears 317 are uniformly disposed, all the first rotation axes cannot be rotated at the same speed by the conventional bevel gears 317. Therefore, the first transmission assembly 31 of the present embodiment further includes a multi-gear set 318, and the multi-gear set 318 can realize the same speed rotation of all the first rotating shafts.

Specifically, the multiple gear set 318 of the present embodiment includes an input gear 318a, a transition gear 318b and an output gear 318c, the input gear 318a, the transition gear 318b and the output gear 318c are sequentially engaged, the input gear 318a is sleeved on a first rotating shaft, the transition gear 318b is pivoted to the rack 10 by taking the length direction of the first rotating shaft as a shaft, and the output gear 318c is sleeved at two ends of the adjacent first rotating shaft. Then, when one of the first rotation shafts is driven to rotate by the bevel gear 317, the input gear 318a rotates, the transition gear 318b and the output gear 318c rotate in sequence, and the rotation of the output gear 318c can drive the rotation of the adjacent first rotation shaft. All the first rotating shafts directly connected to the first connecting rods 311 or not connected to the first connecting rods 311 can be synchronized in speed, so that the FPC flexible printed circuit can be conveyed at a constant speed.

Referring to fig. 1 and fig. 2, the FPC flexible printed circuit board centering device 100 of the present embodiment further includes a first partition plate 70 and a second partition plate 80, wherein the first partition plate 70 is perpendicular to and located in the middle of the first rotation axis, and the second partition plate 80 is perpendicular to and located in the middle of the second rotation axis. In this embodiment, the two sides of the first partition board 70 and the second partition board 80 are used to simultaneously convey the flexible printed circuit boards, so as to improve the conveying efficiency. Furthermore, the FPC flexible printed circuit center positioning machine 100 further includes a fixing baffle 90, the fixing baffle 90 is located at the output end of the transition plate 40, and the fixing baffle 90 is used to prevent the FPC flexible printed circuit from dropping at the output end.

Compared with the prior art, the utility model discloses following beneficial effect has: the utility model discloses a FPC soft board center positioning machine 100 accomplishes the transportation process of whole FPC soft board through first conveyor assembly 21, second conveyor assembly 22, clappers 50 can inside outwards remove multiplicable production product size scope, can fix a position the FPC soft board in transportation process through clapping board 50, and prevents through cab apron 40 that the FPC soft board from dropping in the transfer passage from the delivery wheel clearance.

The basic principles and the main features of the invention and the advantages of the invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. A FPC soft board center positioning machine is used for conveying FPC soft boards and is characterized by comprising a rack, a conveying mechanism, a transmission mechanism, a transition plate and a clapper, wherein the conveying mechanism is arranged on the rack along the horizontal direction, the FPC soft boards are placed on the conveying mechanism, the conveying mechanism comprises a first conveying assembly and a second conveying assembly, the first conveying assembly is connected with the second conveying assembly end to end, the transmission mechanism comprises a first transmission assembly and a second transmission assembly, the first transmission assembly drives the FPC soft boards to move on the first conveying assembly, the second transmission assembly drives the FPC soft boards to move on the second conveying assembly, and the FPC soft boards are conveyed to the input end of the second conveying assembly through the output end of the first conveying assembly; the transition plate is arranged on the second conveying assembly, and the two clapboards simultaneously move inwards or outwards along the left-right direction above the second conveying assembly.

2. The FPC center positioning machine of claim 1, wherein the first conveying assembly comprises a first rotating shaft, a plurality of first rotating shafts are arranged along a direction perpendicular to a moving direction of the FPC, a plurality of first conveying wheels are uniformly sleeved on each first rotating shaft, and the first conveying wheels on two adjacent first rotating shafts are staggered.

3. The FPC center positioning machine of claim 2, wherein the second conveying assembly comprises a plurality of second rotating shafts, a plurality of the second rotating shafts are arranged along a direction perpendicular to the moving direction of the FPC, a plurality of second conveying wheels are sequentially sleeved on each second rotating shaft, a first gap is arranged between the second conveying wheels on the same second rotating shaft, and the transition plate is arranged in the first gap.

4. The FPC centering machine of claim 2, wherein a second interval is provided between a plurality of the first conveying wheels on the first rotating shaft closest to the second conveying assembly, and the front end of the transition plate extends to between the second interval and above the first rotating shaft.

5. The FPC center positioning machine of claim 1, further comprising a flap pushing structure for pushing the flap to move, wherein the flap pushing structure is located below the second conveying assembly, the flap pushing structure comprises a first motor, a first belt, a driving wheel, a driven wheel, a guide rod, a first fixing member, and a second fixing member, the first motor is vertically disposed on the frame, the driving wheel is located above the first motor and connected to an output end of the first motor, the driving wheel is connected to the driven wheel via the first belt, the driving wheel and the driven wheel are respectively located below the corresponding flaps, the guide rod is disposed on the frame along the second rotation axis direction, the first fixing member and the second fixing member are slidably disposed on the guide rail, and the first fixing member is connected to one of the flaps, the second fixing piece is connected to the other clapper, and the first fixing piece and the second fixing piece are fixed to two sides of the first belt respectively.

6. The FPC board centering machine of claim 3, wherein the first transmission assembly comprises a first link, the second transmission assembly comprises a second link, the first link is perpendicular to the first rotation axis, and the second link is perpendicular to the second rotation axis; the two first connecting rods are positioned at two ends of the plurality of first rotating shafts, and the two second connecting rods are positioned at two ends of the second rotating shafts.

7. The FPC soft board center positioning machine of claim 6, wherein the first transmission assembly further comprises a second motor, a second belt, a third belt, a fourth belt conveyor and a gear box, the second motor is horizontally arranged right below one of the first connecting rods, and the gear box is horizontally arranged right below the other first connecting rod; the second belt and the fourth belt are arranged along the vertical direction, and the third belt is arranged along the horizontal direction; one end of the second belt is sleeved on the corresponding first connecting rod, and the other end of the second belt is sleeved on the output end of the second motor; one end of the third belt is sleeved at the output end of the second motor, and the other end of the third belt is sleeved at the input end of the gear box; one end of the fourth belt is sleeved on the output end of the gear box, and the fourth belt is sleeved on the corresponding first connecting rod.

8. The FPC center positioning machine of claim 6, wherein the first transmission assembly further comprises a plurality of bevel gears, the bevel gears comprise a first gear and a second gear, an axis of the first gear is perpendicular to an axis of the second gear, the first gear is engaged with the second gear, the plurality of first gears are sleeved on the first connecting rod or the second connecting rod, and the second gear is connected to two ends of the first rotating shaft or the second rotating shaft.

9. The FPC soft board center positioning machine of claim 2, wherein the first transmission assembly further comprises a multi-gear set, the multi-gear set comprises an input gear, a transition gear and an output gear, the input gear, the transition gear and the output gear are sequentially meshed, the input gear is sleeved on the first rotating shaft, the transition gear is pivoted to the frame by taking the length direction of the first rotating shaft as a shaft, and the output gear is sleeved at two ends of the adjacent first rotating shaft.

10. The FPC center positioning machine of claim 3, further comprising a first partition plate, a second partition plate, and a fixed baffle, wherein the first partition plate is perpendicular to and located in the middle of the first rotation axis, and the second partition plate is perpendicular to and located in the middle of the second rotation axis; the fixed baffle is positioned at the output end of the transition plate.

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