CN220484537U - Multi-size feeder of high-speed chip mounter - Google Patents

Abstract

The utility model discloses a multi-size feeder of a high-speed chip mounter, which relates to the field of feeding equipment and comprises a supporting plate, wherein four supporting rods are symmetrically and fixedly arranged on the supporting plate, the same supporting frame is fixedly arranged on the four supporting rods, a first motor is fixedly arranged on one side of the supporting frame, a conveying structure is arranged at the output end of the first motor, a connecting plate is fixedly arranged on the supporting frame, and a fixing frame is fixedly arranged on one side of the connecting plate. According to the utility model, through the arrangement of the structures such as the conveying belt and the limiting plates, the PCB can be placed on the conveying belt through the movable holes, the conveying belt can be circularly moved by driving the first motor, so that the PCB can be conveyed and fed, the PCB can be positioned through the arrangement of the two limiting plates, the position of the PCB is prevented from being deviated in the conveying process, and the distance between the two limiting plates can be adjusted by driving the second motor, so that the PCB with different sizes can be positioned and conveyed.

Description

Multi-size feeder of high-speed chip mounter

Technical Field

The utility model relates to the technical field of feeding equipment, in particular to a multi-size feeder of a high-speed chip mounter.

Background

The high-speed chip mounter is a device for accurately placing and fixing chip components at corresponding positions of a PCB.

In the prior art, the high-speed chip mounter feeder can be used for conveying the PCB (printed circuit board) so that the high-speed chip mounter can carry out chip mounting processing, but in order to prevent the position of the PCB from shifting in the conveying process, a baffle plate is required to be arranged on the feeder to position the PCB, but when the PCB with different sizes is conveyed, the distance of the baffle plate needs to be manually adjusted, and the feeding device is more complicated, so that the multi-size feeder of the high-speed chip mounter is required to meet the demands of people.

Disclosure of Invention

The utility model aims to provide a multi-size feeder of a high-speed chip mounter, which aims to solve the problems that in order to prevent the position of a PCB from shifting in the conveying process, a baffle plate is required to be arranged on the feeder to position the PCB, but the distance of the baffle plate is required to be manually adjusted when the PCBs with different sizes are conveyed, and the operation is complicated.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a multi-size feeder of high-speed chip mounter, includes the backup pad, symmetrical fixed mounting has four bracing pieces in the backup pad, fixed mounting has same support frame on four bracing pieces, one side fixed mounting of support frame has first motor, conveying structure is installed to the output of first motor, fixed mounting has the connecting plate on the support frame, one side fixed mounting of connecting plate has the mount, fixed mounting has the second motor on the mount, the output fixed mounting of second motor has the linkage carousel, install limit structure on the linkage carousel, the upside fixed mounting of bracing piece has the third motor, the output of third motor runs through the backup pad and fixed mounting has adjusting gear, install adjusting structure on the adjusting gear.

Preferably, the conveying structure comprises two connecting shafts, the two connecting shafts are rotatably arranged on the supporting frame, driving rollers are fixedly arranged on the two connecting shafts, the same conveying belt is arranged on the two driving rollers in a transmission mode, and the output end of the first motor is fixedly arranged on the corresponding connecting shaft.

Preferably, the limit structure comprises two linkage rods, one ends of the two linkage rods are rotatably mounted on the linkage turntable, the other ends of the two linkage rods are rotatably mounted with linkage racks, the two linkage racks are slidably mounted on the bottom side of the connecting plate, four fixing plates are symmetrically and fixedly mounted on two sides of the support frame, one linkage rotating shaft is rotatably mounted on the two fixing plates on the same side, one end of the four linkage rotating shafts is fixedly mounted with a linkage gear, the two linkage gears on the same side are meshed with the same linkage rack, the four linkage rotating shafts are fixedly mounted with adjusting rods, the four adjusting rods are movably mounted on the support frame, the limit blocks are rotatably mounted on the four adjusting rods, one sliding rod is slidably mounted on the two limit blocks on the same side, the fixing blocks are fixedly mounted on two ends of the two sliding rods, one side of the two fixing blocks on the same side is fixedly mounted with one limit plate, the two limit plates are slidably mounted on the support frame, and the two ends of the two limit plates are fixedly mounted with baffle plates.

Preferably, the fixed plate is provided with a rotating hole, and the linkage rotating shaft is rotatably arranged in the rotating hole.

Preferably, two linkage holes are formed in the adjusting rod, linkage shafts are rotatably mounted in the two linkage holes, and the two linkage shafts are fixedly mounted on two sides of the limiting block respectively.

Preferably, the limiting block is provided with a sliding hole, and the sliding rod is slidably arranged in the sliding hole.

Preferably, two movable holes are formed in the support frame, and two ends of the limiting plate are respectively and slidably arranged in the two movable holes.

Preferably, the adjusting structure comprises a gear plate rotatably mounted on the bottom side of the support plate, and the gear plate is meshed with the adjusting gear.

The beneficial effects of the utility model are as follows:

according to the utility model, through the arrangement of the structures such as the conveying belt and the limiting plates, the PCB can be placed on the conveying belt through the movable holes, the conveying belt can be circularly moved by driving the first motor, so that the PCB can be conveyed and fed, the PCB can be positioned through the arrangement of the two limiting plates, the position of the PCB is prevented from being deviated in the conveying process, and the distance between the two limiting plates can be adjusted by driving the second motor, so that the PCB with different sizes can be positioned and conveyed.

According to the utility model, through the arrangement of the structures such as the adjusting gear and the gear plate, the third motor is driven to drive the adjusting gear to rotate, and the adjusting gear can move around the gear plate while rotating, so that the moving adjusting gear can drive the supporting plate to move through the third motor, the direction of the conveying belt can be adjusted, the effect of adjusting the conveying direction of the PCB is realized, and the PCB can be conveyed to different conveying belts.

Drawings

Fig. 1 is a schematic structural diagram of a multi-size feeder of a high-speed chip mounter according to the present utility model;

fig. 2 is a schematic structural diagram of a gear plate portion of a multi-size feeder of a high-speed chip mounter according to the present utility model;

fig. 3 is a schematic structural diagram of a connection board portion of a multi-size feeder of the high-speed chip mounter according to the present utility model;

fig. 4 is a schematic cross-sectional structure of a conveyor belt portion of a multi-size feeder of a high-speed chip mounter according to the present utility model;

fig. 5 is a schematic structural diagram of an adjusting rod portion of a multi-size feeder of a high-speed chip mounter according to the present utility model.

In the figure: 100. a support plate; 200. a support rod; 201. a support frame; 202. a first motor; 203. a connecting shaft; 204. a driving roller; 205. a conveyor belt; 300. a fixing frame; 301. a second motor; 302. a linkage turntable; 303. a linkage rod; 304. a linkage rack; 305. a fixing plate; 306. a linkage rotating shaft; 307. a linkage gear; 308. an adjusting rod; 309. a limiting block; 310. a slide bar; 311. a fixed block; 312. a limiting plate; 313. a baffle; 314. a movable hole; 315. a rotation hole; 316. a linkage hole; 317. a linkage shaft; 318. a sliding hole; 319. a connecting plate; 400. a third motor; 401. an adjusting gear; 402. a gear plate.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1 to 5, a multi-sized feeder of a high-speed chip mounter includes a supporting plate 100, four supporting rods 200 are symmetrically and fixedly installed on the supporting plate 100, the same supporting frame 201 is fixedly installed on the four supporting rods 200, a first motor 202 is fixedly installed on one side of the supporting frame 201, a conveying structure is installed at an output end of the first motor 202, a connecting plate 319 is fixedly installed on the supporting frame 201, a fixing frame 300 is fixedly installed on one side of the connecting plate 319, a second motor 301 is fixedly installed on the fixing frame 300, a linkage turntable 302 is fixedly installed at an output end of the second motor 301, a limiting structure is installed on the linkage turntable 302, a third motor 400 is fixedly installed at a top side of the supporting rod 200, an output end of the third motor 400 penetrates through the supporting plate 100 and is fixedly installed with an adjusting gear 401, an adjusting structure is installed on the adjusting gear 401, the first motor 202 can be driven when in use, the output end of the first motor 202 drives one of the connecting shafts 203 to rotate, the rotating connecting shaft 203 drives the driving roller 204 to rotate, the driving roller 204 drives the other driving roller 204 to rotate with the connecting shaft 203 through the cooperation with the conveying belt 205 while the conveying belt 205 rotates, the conveying belt 205 rotates circularly, the PCB board can be placed on the conveying belt 205 through the movable hole 314, the transferring and feeding of the PCB board can be realized through the circular rotation of the conveying belt 205, the second motor 301 can be driven, the output end of the second motor 301 drives the linkage turntable 302 to rotate, the linkage turntable 302 rotates while one ends of the two linkage rods 303 are driven to rotate and move, so that the other ends of the linkage rods 303 pull the linkage racks 304 to slide horizontally on the connecting plate 319, the horizontally sliding linkage racks 304 drive the two linkage gears 307 to rotate towards the side close to each other through the meshing with the two linkage gears 307, the linkage gear 307 which rotates drives the linkage rotating shaft 306 to rotate in the rotating holes 315 on the two fixed plates 305, offset is avoided, the linkage rotating shaft 306 which continuously rotates drives one end of the adjusting rod 308 to rotate, the other end of the adjusting rod 308 is matched with the linkage shaft 317 to extrude the limiting block 309 to move, the moving limiting block 309 slides on the sliding rod 310 through the sliding hole 318, the moving direction of the limiting block 309 is further limited, the limiting block 309 can drive the limiting plate 312 to move while moving, the moving limiting plate 312 can move in the moving hole 314 and drive the baffle 313 to move, the moving baffle 313 can shade one side of the moving hole 314, the space of the moving hole 314 is reduced, accordingly, the effect that the two limiting plates 312 are mutually close to each other to move can be achieved in the rotating process of the linkage turntable 302, the distance between the two limiting plates 312 can be adjusted according to the size of a conveyed PCB, the PCB can be prevented from being offset when the PCB is conveyed, and the third motor 400 can drive the adjusting gear 401 to rotate through driving the adjusting gear 401 to be meshed with the gear plate 402, the adjusting gear 401 can move around the gear 205, the gear 402 can move towards the third motor, and the conveying plate 400 can be driven to move, and the third motor 400 can move towards the conveying direction of the PCB 400.

Further, the conveying structure comprises two connecting shafts 203, the two connecting shafts 203 are rotatably arranged on the supporting frame 201, driving rollers 204 are fixedly arranged on the two connecting shafts 203, the same conveying belt 205 is arranged on the two driving rollers 204 in a transmission mode, the output end of the first motor 202 is fixedly arranged on one corresponding connecting shaft 203, the first motor 202 is driven, the output end of the first motor 202 can drive one connecting shaft 203 to rotate, the rotating connecting shaft 203 can drive the driving rollers 204 to rotate, the driving rollers 204 can drive the other driving roller 204 to rotate with the connecting shaft 203 through the cooperation of the conveying belt 205, meanwhile, the conveying belt 205 can circularly rotate, and a PCB (printed circuit board) can be placed on the conveying belt 205 through the movable holes 314, and the transfer and the feeding of the PCB can be realized through the circular rotation of the conveying belt 205.

Further, the limiting structure comprises two linkage rods 303, one ends of the two linkage rods 303 are rotatably arranged on the linkage turntable 302, the other ends of the two linkage rods 303 are rotatably provided with linkage racks 304, the two linkage racks 304 are slidably arranged at the bottom side of the connecting plate 319, four fixing plates 305 are symmetrically and fixedly arranged at two sides of the supporting frame 201, one linkage rotating shaft 306 is rotatably arranged on the two fixing plates 305 at the same side, one ends of the four linkage rotating shafts 306 are fixedly provided with linkage gears 307, the two linkage gears 307 at the same side are meshed with the one linkage rack 304, the four linkage rotating shafts 306 are fixedly provided with adjusting rods 308, the four adjusting rods 308 are movably arranged on the supporting frame 201, the four adjusting rods 308 are rotatably provided with limiting blocks 309, the two limiting blocks 309 at the same side are slidably provided with one sliding rod 310, the two ends of the two sliding rods 310 are fixedly provided with the fixed blocks 311, one side of the two fixed blocks 311 positioned on the same side is fixedly provided with the same limiting plate 312, the two limiting plates 312 are slidably arranged on the supporting frame 201, the two ends of the two limiting plates 312 are fixedly provided with the baffle 313, the second motor 301 is driven, the output end of the second motor 301 can drive the linkage turntable 302 to rotate, the linkage turntable 302 can drive one end of the two linkage rods 303 to rotate and move while driving one end of the linkage turntable 302 to rotate, so that the other end of the linkage rod 303 pulls the linkage rack 304 to horizontally slide on the connecting plate 319, the horizontally sliding linkage rack 304 can respectively drive the two linkage gears 307 to rotate towards the side close to each other through the meshing of the two linkage gears 307, the rotating linkage gears 307 can drive the linkage rotating shaft 306 to rotate in the rotating holes 315 on the two fixed plates 305, avoid taking place the skew, the linkage pivot 306 of continuous rotation can drive the one end rotation of adjusting the pole 308 for the other one end of adjusting the pole 308 passes through the cooperation extrusion stopper 309 of linkage hole 316 with the linkage shaft 317 and removes, make the stopper 309 of removal slide on slide bar 310 through slide hole 318, and then restricted the direction of movement of stopper 309, the limiting plate 312 removal can be driven to the stopper 309 when removing, the limiting plate 312 of removal can move in movable hole 314 and drive baffle 313 and remove, the baffle 313 of removal can shelter from the one side of movable hole 314, reduce the space of movable hole 314, thereby can realize the effect that two limiting plates 312 are close to each other and remove at linkage carousel 302 pivoted in-process, can adjust the distance between two limiting plates 312 according to the PCB size of carrying.

Further, the fixing plates 305 are provided with rotation holes 315, the linkage rotating shafts 306 are rotatably installed in the rotation holes 315, and the rotation linkage gears 307 drive the linkage rotating shafts 306 to rotate in the rotation holes 315 on the two fixing plates 305, so as to avoid deviation.

Further, two linkage holes 316 are formed in the adjusting rod 308, linkage shafts 317 are rotatably mounted in the two linkage holes 316, the two linkage shafts 317 are fixedly mounted on two sides of the limiting block 309 respectively, and the continuously rotating linkage shaft 306 drives one end of the adjusting rod 308 to rotate, so that the other end of the adjusting rod 308 extrudes the limiting block 309 to move through the cooperation of the linkage holes 316 and the linkage shafts 317.

Further, the limiting block 309 is provided with a sliding hole 318, the sliding rod 310 is slidably mounted in the sliding hole 318, and the moving limiting block 309 slides on the sliding rod 310 through the sliding hole 318, so as to limit the moving direction of the limiting block 309.

Further, two movable holes 314 are formed in the supporting frame 201, two ends of the limiting plate 312 are slidably mounted in the two movable holes 314, and the moving limiting plate 312 moves in the movable holes 314 and drives the baffle 313 to move.

Further, the adjusting structure comprises a gear plate 402, the gear plate 402 is rotatably arranged at the bottom side of the supporting plate 100, the gear plate 402 is meshed with the adjusting gear 401, the adjusting gear 401 is driven to rotate by driving the third motor 400, and the adjusting gear 401 is meshed with the gear plate 402, so that the adjusting gear 401 can move around the gear plate 402 when the adjusting gear 401 rotates, the adjusting gear 401 can drive the third motor 400 to move, the moving third motor 400 can drive the supporting plate 100 to move, the direction of the conveying belt 205 can be adjusted, and the conveying direction of the PCB can be adjusted.

The working principle of the utility model is as follows:

when in use, the first motor 202 can be driven, the output end of the first motor 202 can drive one of the connecting shafts 203 to rotate, the rotating connecting shaft 203 can drive the driving roller 204 to rotate, the driving roller 204 can drive the other driving roller 204 and the connecting shaft 203 to rotate through the cooperation with the conveying belt 205 while rotating, the conveying belt 205 can circularly rotate, the PCB board can be placed on the conveying belt 205 through the movable hole 314, the transfer and feeding of the PCB board can be realized through the circularly rotation of the conveying belt 205, the second motor 301 can be driven, the output end of the second motor 301 can drive the linkage turntable 302 to rotate, the linkage turntable 302 can drive one ends of the two linkage rods 303 to rotate and move while rotating, thereby the other ends of the linkage rods 303 pull the linkage racks 304 to horizontally slide on the connecting plates 319, the horizontally sliding linkage racks 304 can respectively drive the two linkage gears 307 to rotate towards the side close to each other through the meshing with the two linkage gears 307, the rotating linkage gear 307 drives the linkage rotating shaft 306 to rotate in the rotating holes 315 on the two fixed plates 305 to avoid deviation, the continuously rotating linkage rotating shaft 306 drives one end of the adjusting rod 308 to rotate, the other end of the adjusting rod 308 is matched with the linkage shaft 317 to press the limiting block 309 to move through the linkage hole 316, the moving limiting block 309 slides on the sliding rod 310 through the sliding hole 318, the moving direction of the limiting block 309 is further limited, the limiting block 309 moves and drives the limiting plate 312 to move, the moving limiting plate 312 moves in the movable hole 314 and drives the baffle 313 to move, the moving baffle 313 can shield one side of the movable hole 314, the space of the movable hole 314 is reduced, the effect that the two limiting plates 312 move close to each other can be achieved in the rotating process of the linkage turntable 302, the distance between two limiting plates 312 can be adjusted according to the size of the conveyed PCB, so that the PCB can be prevented from being deviated when the PCB is conveyed, the third motor 400 can be driven to drive the adjusting gear 401 to rotate, and the adjusting gear 401 and the gear plate 402 are meshed with each other, so that the adjusting gear 401 can move around the gear plate 402 when the adjusting gear 401 rotates, the adjusting gear 401 can drive the third motor 400 to move, the moving third motor 400 can drive the supporting plate 100 to move, the direction of the conveying belt 205 can be adjusted, and the conveying direction of the PCB can be adjusted.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (8)

1. The utility model provides a high-speed chip mounter's multisize feeder, includes backup pad (100), its characterized in that: four bracing pieces (200) are symmetrically and fixedly installed on the supporting plate (100), the same supporting frame (201) is fixedly installed on the four bracing pieces (200), a first motor (202) is fixedly installed on one side of the supporting frame (201), a conveying structure is installed at the output end of the first motor (202), a connecting plate (319) is fixedly installed on the supporting frame (201), a fixing frame (300) is fixedly installed on one side of the connecting plate (319), a second motor (301) is fixedly installed on the fixing frame (300), a linkage turntable (302) is fixedly installed at the output end of the second motor (301), a limiting structure is installed on the linkage turntable (302), a third motor (400) is fixedly installed on the top side of the bracing piece (200), the output end of the third motor (400) penetrates through the supporting plate (100) and is fixedly provided with an adjusting gear (401), and an adjusting structure is installed on the adjusting gear (401).

2. The multi-size feeder of a high-speed chip mounter according to claim 1, wherein: the conveying structure comprises two connecting shafts (203), the two connecting shafts (203) are rotatably arranged on a supporting frame (201), driving rollers (204) are fixedly arranged on the two connecting shafts (203), the same conveying belt (205) is arranged on the two driving rollers (204) in a transmission mode, and the output end of a first motor (202) is fixedly arranged on one corresponding connecting shaft (203).

3. The multi-size feeder of a high-speed chip mounter according to claim 1, wherein: the limiting structure comprises two linkage rods (303), one ends of the two linkage rods (303) are rotatably arranged on a linkage turntable (302), the other ends of the two linkage rods (303) are rotatably provided with linkage racks (304), the two linkage racks (304) are slidably arranged on the bottom side of a connecting plate (319), four fixing plates (305) are symmetrically and fixedly arranged on two sides of the supporting frame (201), one linkage rotating shaft (306) is rotatably arranged on the two fixing plates (305) on the same side, one ends of the four linkage rotating shafts (306) are fixedly provided with linkage gears (307), the two linkage gears (307) on the same side are meshed with one linkage rack (304), the four linkage rotating shafts (306) are fixedly provided with adjusting rods (308), the four adjusting rods (308) are movably arranged on the supporting frame (201), limiting blocks (309) are rotatably arranged on the four adjusting rods (308), one sliding rod (310) is slidably arranged on the two limiting blocks (309) on the same side, two ends of the two sliding rods (310) are fixedly arranged on two limiting blocks (311) on the same side, one side of the two limiting plates (312) are fixedly arranged on the same side of the limiting plates (312), baffle plates (313) are fixedly arranged at two ends of the two limiting plates (312).

4. A multi-size feeder of a high speed chip mounter according to claim 3, wherein: the fixed plate (305) is provided with a rotating hole (315), and the linkage rotating shaft (306) is rotatably arranged in the rotating hole (315).

5. A multi-size feeder of a high speed chip mounter according to claim 3, wherein: two linkage holes (316) are formed in the adjusting rod (308), linkage shafts (317) are rotatably mounted in the two linkage holes (316), and the two linkage shafts (317) are fixedly mounted on two sides of the limiting block (309) respectively.

6. A multi-size feeder of a high speed chip mounter according to claim 3, wherein: the limiting block (309) is provided with a sliding hole (318), and the sliding rod (310) is slidably arranged in the sliding hole (318).

7. The multi-size feeder of a high-speed chip mounter according to claim 1, wherein: two movable holes (314) are formed in the support frame (201), and two ends of the limiting plate (312) are respectively and slidably arranged in the two movable holes (314).

8. The multi-size feeder of a high-speed chip mounter according to claim 1, wherein: the adjusting structure comprises a gear plate (402), the gear plate (402) is rotatably arranged on the bottom side of the supporting plate (100), and the gear plate (402) is meshed with the adjusting gear (401).