CN216888756U - Feeding equipment capable of arranging materials at stable intervals - Google Patents

Abstract

The utility model provides a feeding device capable of arranging materials at stable intervals. The material guide rotary table is rotatably arranged on the base body, the arraying device comprises a cover plate, a feeding guide rail piece and a discharging guide rail piece, the cover plate is connected with the base body and is suspended on the material guide rotary table, the discharging guide rail piece is provided with a guide plane along the discharging direction, the guide plane is provided with a vacuum adsorption hole, and the vacuum adsorption hole generates negative pressure suction force through vacuumizing, so that the material can be attached to the guide plane until falling on the test rotary table when being guided out by the discharging guide rail piece; the blowing device is arranged on one side of the discharging guide rail part and is provided with a blowing hole, and the blowing hole blows air towards the material which is displaced along the discharging direction.

Description

Feeding equipment capable of arranging materials at stable intervals

Technical Field

The present invention relates to a feeding device, and more particularly to a feeding device capable of arranging materials at a stable interval.

Background

The existing feeding device conveys materials by rotating a material guide rotary table, moves the materials to a test rotary table of a testing machine after being aligned, and performs the processes of counting the materials, detecting the appearance and the like by rotating the test rotary table.

Since the materials are generally light in weight and small in size (such as a micro ceramic capacitor), two materials are easily adhered to each other due to static electricity during the alignment process and transferred to the test turntable, so that the materials are not arranged on the test turntable, which affects the accuracy of material appearance detection, and even affects the material conveying speed and reduces the operation efficiency.

SUMMERY OF THE UTILITY MODEL

In order to solve the above problems, the present invention provides a feeding device capable of arranging materials at a stable interval, wherein the materials are uniformly arranged by vacuum adsorption and blowing during material guiding, and are stably transported in an array and guided to a test turntable, thereby avoiding abnormal detection.

The utility model provides a feeding device capable of arranging materials at stable intervals, which is arranged on one side of a test turntable and used for arranging and transmitting the materials to the test turntable. The material guide rotary disc is rotatably arranged on the base body, and the position of the material guide rotary disc is higher than that of the test rotary disc; the arraying device comprises a cover plate, a feeding guide rail piece and a discharging guide rail piece, wherein the cover plate is connected with the base body and is suspended on the material guide turntable, the cover plate is provided with a feeding part and a discharging part, the feeding guide rail piece is arranged at the position of the feeding part, the discharging guide rail piece is arranged at the position of the discharging part, the discharging guide rail piece is provided with a guide plane along a discharging direction, the guide plane is provided with a vacuum adsorption hole, and the vacuum adsorption hole generates negative pressure suction force through vacuumizing so that the material can be attached to the guide plane until falling on the test turntable when being guided out by the discharging guide rail piece; the blowing device is arranged on one side of the discharging guide rail part and is provided with a blowing hole, and the blowing hole blows air towards the material which is displaced along the discharging direction.

In a preferred embodiment, the discharge guide rail member has an inner air passage and a connecting pipe member, one end of the inner air passage is communicated with the vacuum absorption hole, and the other end of the inner air passage is communicated with the connecting pipe member.

In a preferred embodiment, the inner air passage includes a small-diameter air passage and a large-diameter air passage, the large-diameter air passage is communicated between the small-diameter air passage and the connecting pipe, and the small-diameter air passage is communicated between the large-diameter air passage and the vacuum absorption hole.

In a preferred embodiment, the air blowing holes have an inclination angle relative to the guide plane, and the inclination angle is 5 degrees.

In a preferred embodiment, the level of the air blowing hole is higher than that of the vacuum suction hole.

In a preferred embodiment, the discharge guide rail part has a vertical surface perpendicular to the guide plane, the air blowing device has an inclined surface, the air blowing hole is arranged on the inclined surface, and the inclined surface is inclined relative to the vertical surface.

In a preferred embodiment, the blowing device is fixed on the cover plate.

In a preferred embodiment, the cover plate has a first side, a second side and a third side between the first side and the second side, the cover plate is hinged to the base at the first side, and a handle for holding and lifting the cover plate is arranged at the second side; the cover plate is clamped on the third side edge.

In a preferred embodiment, the third side has a connecting edge adjacent to the first side, the blowing holes are located outside the connecting edge, and the vacuum suction holes are located inside the connecting edge.

In a preferred embodiment, the material guiding device further comprises a hopper, wherein the hopper can move above the cover plate and is communicated with the material feeding part, and the material can be poured from the hopper and is discharged to the material guiding turntable through the material feeding part.

Therefore, when the materials are led out from the feeding equipment to the testing turntable, the static electricity among the materials is eliminated in a vacuum adsorption and air blowing mode, the materials are adhered without intervals, the materials are arranged at uniform intervals, and the problem of abnormal follow-up detection is avoided.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic perspective view of a feeding device of an embodiment of the present invention disposed beside a test turntable.

FIG. 2 is a schematic top view of a feed apparatus according to an embodiment of the present invention.

Fig. 3 is a partially enlarged schematic view at a of fig. 1.

FIG. 4 is an enlarged partial schematic view of the outfeed rail member of FIG. 2.

FIG. 5 is a schematic view of the blowing device of the embodiment of the present invention blowing air in the discharging direction.

Description of the reference numerals

100: feeding equipment

200: test turntable

10: base body

20: material guiding rotary disc

30: arraying device

31: cover plate

31 a: feeding part

31 b: discharge part

311: inner side surface

312: the first side edge

313: second side edge

314: third side edge

315: connecting edge

316: handle bar

32: feeding guide rail part

33: relay guide member

34: discharge guide rail part

341: inner end

342: outer end of

343: guide plane

344: vacuum adsorption hole

342 a: vertical surface

345: inner air passage

3451: small-diameter air passage

3452: large-diameter air passage

346: pipe connecting piece

40: air blowing device

41: air blowing hole

42: inclined plane

50: hopper

C: miniature ceramic capacitor

D: direction of discharge

θ: and (4) inclining the angle.

Detailed Description

To facilitate the explanation of the present invention, the following description will be made with reference to the accompanying drawings. The various materials of the embodiments are depicted in a suitable scale, size, amount of deformation or displacement for illustration, rather than in the scale of actual components, as previously described.

Referring to fig. 1 to 5, the present invention provides a feeding apparatus 100 for arranging materials at a stable interval, which is disposed at one side of a test turntable 200, and aligns and transfers the materials to the test turntable 200, so as to perform appearance inspection by transferring the test turntable 200. The feeding device 100 includes a base 10, a material guiding turntable 20, an aligning device 30, and an air blowing device 40, wherein the material is a micro ceramic capacitor C.

The base 10 is disposed adjacent to one side of the test turntable 200. The base 10 is provided with a hopper 50 on the other side of the test turntable 200.

The material guiding rotary table 20 is rotatably disposed on the base 10, and the position of the material guiding rotary table 20 is higher than that of the test rotary table 200. In the embodiment of the present invention, the material guiding turntable 20 and the testing turntable 200 are partially intersected.

The arraying device 30 includes a cover plate 31, a feeding rail 32, a relay rail 33, and a discharging rail 34, wherein the feeding rail 32, the relay rail 33, and the discharging rail 34 are disposed on an inner side 311 of the cover plate 31 and between the cover plate 31 and the material guiding turntable 20. The cover plate 31 is coupled to the base 10 and suspended on the material guiding turntable 20. in the embodiment of the utility model, the cover plate 31 has a first side 312, a second side 313 and a third side 314 located between the first side 312 and the second side 313, and the third side 314 has a connecting side 315 adjacent to the first side 312. The cover 31 is hinged to the base 10 at a first side 312, and a handle 316 is disposed at a second side 313 of the cover 31 for holding and lifting the cover 31.

The cover plate 31 has a feeding portion 31a and a discharging portion 31b, the feeding rail 32 is disposed at the position of the feeding portion 31a, and the feeding portion 31a is located at the center of the cover plate 31 in the embodiment of the present invention. Therefore, when the cover plate 31 is in a covering shape, the hopper 50 can move to the upper side of the cover plate 31 and is communicated with the feeding part 31a, so that the micro ceramic capacitor C can be poured from the hopper 50 and is discharged to the material guiding turntable 20 through the feeding part 31 a. The number of the relay rail members 33 is plural, and the relay rail members are arranged around the feeding rail member 32 in a gradually expanding manner.

The discharge rail member 34 is substantially in a long shape, the discharge rail member 34 is disposed at the position of the discharge portion 31b, and the discharge rail member 34 has an inner end 341 and an outer end 342, the inner end 341 is located at the inner side of the connecting edge 315, and the outer end 342 protrudes out of the connecting edge 315. The discharge guide rail member 34 is provided with a guide plane 343 along a discharge direction D, the guide plane 343 has a vacuum absorption hole 344, the aperture of the vacuum absorption hole 344 is smaller than the overall dimension of the micro ceramic capacitor C, so that the vacuum absorption hole 344 generates a negative pressure suction force by vacuum pumping, and the micro ceramic capacitor C can be attached to the guide plane 343 until falling on the test turntable 200 when being led out by the discharge guide rail member 34, so that the resistance effect generated by the vacuum suction force can smoothly separate the micro ceramic capacitors C in the front-back sequence to generate a space, and the micro ceramic capacitors C are not easily adhered to each other and are sequentially and uniformly introduced onto the test turntable 200 at regular intervals. In addition, the discharge rail member 34 has a vertical face 342a at the outer end 342 perpendicular to the guide plane 343.

As shown in fig. 4, in the embodiment of the present invention, the discharging rail member 34 has an inner air passage 345 and a pipe connecting member 346. The connection member 346 is used to communicate with a vacuum generator, one end of the inner air channel 345 communicates with the vacuum absorption hole 344, and the other end of the inner air channel 345 communicates with the connection member 346. The inner gas duct 345 includes a small-diameter gas duct 3451 and a large-diameter gas duct 3452, the large-diameter gas duct 3452 is connected between the small-diameter gas duct 3451 and the connecting pipe 346, the small-diameter gas duct 3451 is connected between the large-diameter gas duct 3452 and the vacuum absorption hole 344, and the vacuum absorption hole 344 at the open end of the small-diameter gas duct 3451 can achieve a better absorption capacity so as to stably absorb the micro ceramic capacitor C.

The air blowing device 40 is arranged on one side of the discharging guide rail member 34, the air blowing device 40 is provided with an air blowing hole 41, the air blowing device 40 blows air towards the micro ceramic capacitors C which are displaced along the discharging direction D, so that the electrostatic effect among the micro ceramic capacitors C is eliminated, the micro ceramic capacitors C are separated, the micro ceramic capacitors C can be orderly arranged at intervals and output along the guide plane 343, and the guide speed is improved. Wherein, the blowing device 40 is connected to an ion gas generator, so that the blowing device 40 blows out from the blowing holes 41 by ion wind.

In the embodiment of the present invention, the blowing device 40 is fixed to the cover plate 31 and is clamped to the third side 314 of the cover plate 31 at a position adjacent to the connecting edge 315. The air blowing device 40 has a slope 42, the air blowing hole 41 is disposed on the slope 42, and the slope 42 is inclined with respect to the vertical surface 342 a. In addition, as shown in fig. 5, the blowing holes 41 have an inclination angle θ relative to the guide plane 343, and the inclination angle θ is smaller than 30 degrees, for example, 5 degrees.

In other embodiments of the present invention, the level of the air blowing holes 41 is higher than that of the vacuum suction holes 344. The air blowing hole 41 is located outside the connecting side 315, and the vacuum suction hole 344 is located inside the connecting side 315.

As described above, when the appearance of the micro ceramic capacitor C is to be inspected, a large number of micro ceramic capacitors C are poured from the hopper 50, and the micro ceramic capacitors C are transferred to the feeding portion 31a, and then are discharged onto the material guiding turntable 20, and then are guided to the intermediate guide rail 33 by the feeding guide rail 32, guided to the discharging guide rail 34 by the intermediate guide rail 33, and are arranged along the discharging direction D and output by the discharging portion 31b by the rotation of the material guiding turntable 20. When the micro ceramic capacitors C are guided to the discharging portion 31b, the air blowing device 40 blows air toward the micro ceramic capacitors C displaced along the discharging direction D, so as to eliminate the electrostatic effect of each micro ceramic capacitor C, arrange the micro ceramic capacitors C in order, and assist in separation. In addition, the micro ceramic capacitors C can be adsorbed on the guide plane 343 and conveyed along the discharging direction D by the negative pressure suction force generated by the vacuum adsorbing holes 344, and the micro ceramic capacitors C in the front-back sequence can be smoothly separated to generate intervals, so that the micro ceramic capacitors C are sequentially arranged at intervals and output until falling on the test turntable 200, and then the unqualified micro ceramic capacitors C are removed by detection.

The characteristics of the utility model can be easily found from the above description:

1. according to the utility model, the vacuum adsorption holes 344 of the guide plane 343 generate negative pressure suction force, so that the micro ceramic capacitors C are adsorbed and attached to the guide plane 343 in the process of array transmission, and the micro ceramic capacitors C in the front-back sequence can be smoothly separated to generate intervals by using the resistance effect generated by the vacuum suction force, so that the micro ceramic capacitors C are not easy to stick to each other, and are orderly arranged and guided into and fall on the test turntable 200, thereby avoiding the occurrence of abnormal problems in subsequent retrieval.

2. According to the utility model, the air blowing device 40 is used for blowing air towards the micro ceramic capacitors C which are displaced along the discharging direction D, so that the electrostatic effect among the micro ceramic capacitors C is eliminated, the micro ceramic capacitors C are separated and are not easy to stick together, the micro ceramic capacitors C can be arranged at uniform intervals and are output regularly along the guide plane 343, and the guide speed is increased.

The above examples are only for illustrating the present invention and are not to be construed as limiting the scope of the present invention. It will be understood that various modifications and changes may be made without departing from the spirit of the utility model.

Claims (10)

1. The utility model provides a make feeding equipment that material can arrange with stabilizing interval, its one side of locating a test carousel for supply the material permutation and transmit to this test carousel, its characterized in that includes:

a base body;

the material guide rotary disc is rotatably arranged on the base body, and the position of the material guide rotary disc is higher than that of the test rotary disc;

the arraying device comprises a cover plate, a feeding guide rail piece and a discharging guide rail piece, wherein the cover plate is connected with the base body and is suspended on the material guide turntable, the cover plate is provided with a feeding part and a discharging part, the feeding guide rail piece is arranged at the position of the feeding part, the discharging guide rail piece is arranged at the position of the discharging part, the discharging guide rail piece is provided with a guide plane along a discharging direction, the guide plane is provided with a vacuum adsorption hole, and the vacuum adsorption hole generates negative pressure suction force through vacuumizing so that the material can be attached to the guide plane until falling on the test turntable when being led out from the discharging guide rail piece; and

and the air blowing device is arranged on one side of the discharging guide rail part and is provided with an air blowing hole which blows air towards the material which is displaced along the discharging direction.

2. The apparatus as claimed in claim 1, wherein the discharge guide rail member has an inner air passage and a pipe connecting member, one end of the inner air passage is connected to the vacuum adsorption hole, and the other end of the inner air passage is connected to the pipe connecting member.

3. The apparatus of claim 2, wherein the inner gas passage comprises a small-diameter gas passage and a large-diameter gas passage, the large-diameter gas passage is connected between the small-diameter gas passage and the connecting pipe, and the small-diameter gas passage is connected between the large-diameter gas passage and the vacuum suction hole.

4. A feeding apparatus for enabling materials to be arranged at a stable pitch as claimed in claim 1 or 3, wherein said blowing holes have an inclination angle of 5 ° with respect to said guide plane.

5. The feeding apparatus for allowing materials to be arranged at a stable interval as set forth in claim 4, wherein the level of the air blowing hole is higher than that of the vacuum sucking hole.

6. The feeding apparatus for materials at a constant pitch as set forth in claim 5, wherein the discharge guide member has a straight surface perpendicular to the guide plane, and the air blowing means has an inclined surface, the air blowing hole being provided on the inclined surface, the inclined surface being inclined with respect to the straight surface.

7. The feeding apparatus for materials at a constant interval as set forth in claim 1, wherein the blowing means is fixedly provided to the cover plate.

8. The feeding apparatus as claimed in claim 7, wherein the cover has a first side, a second side and a third side between the first side and the second side, the cover is hinged to the base at the first side, and a handle is provided at the second side for holding and lifting the cover, the cover is clamped to the third side.

9. The apparatus of claim 8, wherein the third side has a connecting edge adjacent to the first side, the blowing holes are located at an outer side of the connecting edge, and the vacuum suction holes are located at an inner side of the connecting edge.

10. The feeding apparatus as claimed in claim 9, further comprising a hopper, wherein the hopper can be moved above the cover plate and is connected to the feeding portion, and the material can be poured from the hopper and fed to the material guiding turntable through the feeding portion.

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