CN212268594U - Feeding device for aluminum electrolytic capacitor shell - Google Patents

Abstract

A feeding device for an aluminum electrolytic capacitor shell comprises a vibration disc, wherein a spiral upward spiral track is arranged in the vibration disc, the tail end of the spiral track is in butt joint with an array track, and a first array component and a second array component are arranged on the array track; and at least one height drop of the capacitor shell is arranged between the spiral track and the whole column of tracks. The utility model discloses the high drop that sets up between well spiral track and the permutation track for the shell stands more easily when the shell enters into the permutation track from spiral track, and the proportion of the shell that meets the requirements on the permutation track will improve like this, thereby improves loading attachment's material loading efficiency.

Description

Feeding device for aluminum electrolytic capacitor shell

Technical Field

The utility model relates to an aluminum electrolytic capacitor's apparatus for producing especially relates to a loading attachment of aluminum electrolytic capacitor shell.

Background

In the assembly process of the aluminum electrolytic capacitor production, the shell of the aluminum electrolytic capacitor needs to be conveyed to an assembly device; however, the traditional vibration disk of the aluminum electrolytic capacitor shell is formed by improving the finished product capacitor vibration disk, and the aluminum electrolytic capacitor shell discharged on the whole row of tracks is more, so that the feeding efficiency of the aluminum electrolytic capacitor shell is not high. In the process of feeding the aluminum electrolytic capacitor shell, actually, in the process of selecting the aluminum electrolytic capacitor shell, the inverted and reversed aluminum electrolytic capacitor shell is pushed into the vibration disk again, and the shell with an upward opening is left; and the traditional feeding device has a small number of shells with upward openings when the shells enter the whole column of tracks, so that the feeding efficiency of the shells is influenced.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome the not enough of prior art, provide a loading attachment that aluminium electrolytic capacitor shell material loading efficiency is high.

In order to solve the technical problem, the utility model provides a technical scheme does: a feeding device for an aluminum electrolytic capacitor shell comprises a vibration disc, wherein a spiral upward spiral track is arranged in the vibration disc, the tail end of the spiral track is in butt joint with an array track, and a first array component and a second array component are arranged on the array track; and at least one height drop of the capacitor shell is arranged between the spiral track and the whole column of tracks.

The feeding device for the aluminum electrolytic capacitor shell is preferable, the first array component comprises a first material blocking component and a rolling shell inclined surface, the first material blocking component is arranged above the outer side edge of the array track, and the rolling shell inclined surface is arranged on the array track below the first material blocking component.

In the feeding device for the aluminum electrolytic capacitor shell, preferably, the width of the whole row of tracks at the inclined surface of the rolling shell is smaller than the radius of the aluminum electrolytic capacitor shell; the length of the whole column of tracks at the inclined surface of the rolling shell is greater than the height of the shell of the aluminum electrolytic capacitor.

In the feeding device for the aluminum electrolytic capacitor shell, preferably, a second alignment component is arranged on the alignment track behind the first alignment component, the second alignment component comprises a reverse shell removing device and a second material retaining component, the reverse shell removing device is arranged between the first alignment component and the second material retaining component, and the reverse shell removing device comprises a material removing plate which is wavy or zigzag.

In the above feeding device for the aluminum electrolytic capacitor case, preferably, the center of gravity of the reverse case on the stripper plate deviates from the stripper plate.

The feeding device for the aluminum electrolytic capacitor shell is preferable, the first material blocking assembly and the second material blocking assembly comprise limiting rods and connecting pieces, and the limiting rods are connected to the body of the vibration disc through the connecting pieces.

In the feeding device for the aluminum electrolytic capacitor shell, preferably, the distance between the limiting rod and the array of tracks is greater than the diameter of the aluminum electrolytic capacitor shell and less than the height of the aluminum electrolytic capacitor shell.

Compared with the prior art, the utility model has the advantages of: the utility model discloses the high drop that sets up between well spiral track and the permutation track for the shell stands more easily when the shell enters into the permutation track from spiral track, and the proportion of the shell that meets the requirements on the permutation track will improve like this, thereby improves loading attachment's material loading efficiency.

Drawings

FIG. 1 is a schematic view showing a structure of a charging apparatus for an aluminum electrolytic capacitor case in example 1.

Fig. 2 is an enlarged schematic view of a portion a in fig. 1.

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

Description of the figures

1. A vibrating pan; 2. a spiral track; 3. arranging the tracks in a row; 4. rolling a shell slope; 5. removing the material plate; 6. a limiting rod; 7. a connecting member.

Detailed Description

To facilitate understanding of the present invention, the present invention will be described more fully and specifically with reference to the accompanying drawings and preferred embodiments, but the scope of the present invention is not limited to the specific embodiments described below.

It should be particularly noted that when an element is referred to as being "fixed to, connected to or communicated with" another element, it can be directly fixed to, connected to or communicated with the other element or indirectly fixed to, connected to or communicated with the other element through other intermediate connecting components.

Unless otherwise defined, all terms of art used hereinafter have the same meaning as commonly understood by one of ordinary skill in the art. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the scope of the present invention.

Example 1

The feeding device for the aluminum electrolytic capacitor shell shown in fig. 1 comprises a vibration disc 1, wherein a spiral upward spiral track 2 is arranged in the vibration disc 1, the tail end of the spiral track is butted with an alignment track 3, and a first alignment assembly and a second alignment assembly are arranged on the alignment track 3; at least one height difference of the capacitor shell is arranged between the spiral track 2 and the whole column of tracks 3.

In this embodiment, the width of the entire column of tracks 3 is slightly greater than the diameter of the capacitor housing; when the shell on the spiral track 2 enters the whole column of tracks 3, the shell in the direction of the travel direction of the spiral track 2 mostly stands up when falling onto the whole column of tracks 3; whereas the capacitor case on a conventional vibratory tray 1 is mostly laid on an entire column of rails 3. Of the erected capacitor cases, the case with the opening facing upwards is desirable, and the other cases fall down on the entire row of rails 3 and are returned to the vibration plate 1. In this embodiment, when the casing moves from the spiral track 2 to the alignment track 3, the casing in the traveling direction of the spiral track 2 stands up, so that the number of casings meeting the requirement is increased, and the feeding efficiency of the vibration plate 1 is also improved.

As shown in fig. 2, in this embodiment, the first aligning assembly includes a first material blocking assembly and a rolling shell inclined surface 4, the first material blocking assembly is disposed above the outer side edge of the aligning rail 3, and the rolling shell inclined surface 4 is disposed on the aligning rail 3 below the first material blocking assembly. The width of the whole row of tracks 3 at the inclined surface 4 of the rolling shell is smaller than the radius of the shell of the aluminum electrolytic capacitor; the length of the whole column of tracks 3 at the inclined surface 4 of the rolling shell is greater than the height of the shell of the aluminum electrolytic capacitor.

In this embodiment, when the shell lying on the alignment track 3 moves to the roller shell slope 4, since the width of the alignment track 3 at the roller shell slope 4 is smaller than the radius of the shell of the aluminum electrolytic capacitor, the alignment track 3 at this position is not enough to support the shell, and the shell rolls from the roller shell slope 4 into the vibration plate 1. The limiting rod 6 at the position of the rolling shell inclined plane 4 can not limit the lying shell to roll into the vibration disc 1, so that the distance from the limiting rod 6 to the outer edge of the array track 3 at the position is larger than the diameter of the capacitor shell; but it must also be ensured that the standing casing does not fall into the vibrating disk 1.

As shown in fig. 1, in the present embodiment, a second alignment assembly is disposed on the alignment track 3 behind the first alignment assembly, and the second alignment assembly includes a reverse casing removing device and a second material blocking assembly. As shown in fig. 3, the reverse crust removal means is arranged between the first alignment assembly and the second dam assembly, and the reverse crust removal means comprises a material removal plate 5 in a wave shape or a saw-tooth shape. The center of gravity of the counter shell on the stripper plate 5 is offset from the stripper plate 5.

In this embodiment, when the reversed casing, i.e. the casing with the opening facing downwards, moves onto the stripper plate 5, the reversed casing stands unstably because the stripper plate 5 is wavy or saw-toothed, i.e. the center of gravity of the casing deviates from the stripper plate 5, and the reversed casing falls from the stripper plate 5 into the vibratory pan 1 and is loaded again.

In this embodiment, first fender material subassembly and second fender material subassembly all include gag lever post 6 and connecting piece 7, and gag lever post 6 passes through connecting piece 7 to be connected on the body of vibration dish 1. The distance between the limiting rod 6 and the whole column of tracks 3 is larger than the diameter of the shell of the aluminum electrolytic capacitor and smaller than the height of the shell of the aluminum electrolytic capacitor. In this embodiment, the number of the connecting members 7 between the limiting rod 6 and the vibration plate 1 body may be set to be plural as required.

In this embodiment, the height difference between the spiral track 2 and the alignment track 3 makes the housing stand up more easily when the housing enters the alignment track 3 from the spiral track 2, so that the proportion of the housing meeting the requirements on the alignment track 3 is increased, and the feeding efficiency of the feeding device is improved.

Claims (7)

1. A feeding device for an aluminum electrolytic capacitor shell is characterized in that: the vibration disc is internally provided with a spiral upward spiral track, the tail end of the spiral track is in butt joint with an array track, and the array track is provided with a first array component and a second array component; and at least one height drop of the capacitor shell is arranged between the spiral track and the whole column of tracks.

2. The feeding device of the aluminum electrolytic capacitor shell according to claim 1, characterized in that: the first aligning assembly comprises a first material blocking assembly and a rolling shell inclined plane, the first material blocking assembly is arranged above the outer side edge of the aligning track, and the rolling shell inclined plane is arranged on the aligning track below the first material blocking assembly.

3. The feeding device of the aluminum electrolytic capacitor shell as recited in claim 2, characterized in that: the width of the whole row of tracks at the inclined surface of the rolling shell is smaller than the radius of the shell of the aluminum electrolytic capacitor; the length of the whole column of tracks at the inclined surface of the rolling shell is greater than the height of the shell of the aluminum electrolytic capacitor.

4. The feeding device of the aluminum electrolytic capacitor shell according to claim 1, characterized in that: the second arraying assembly is arranged on the arraying track behind the first arraying assembly and comprises a reverse shell removing device and a second material blocking assembly, the reverse shell removing device is arranged between the first arraying assembly and the second material blocking assembly, and the reverse shell removing device comprises a material removing plate which is wavy or zigzag.

5. The feeding device of the aluminum electrolytic capacitor shell according to claim 1, characterized in that: the center of gravity of the reverse shell on the stripper plate deviates from the stripper plate.

6. The feeding device of the aluminum electrolytic capacitor shell according to claim 2 or 3, characterized in that: first fender material subassembly and second fender material subassembly all include gag lever post and connecting piece, the gag lever post passes through the connecting piece to be connected on the body of vibration dish.

7. The feeding device for the aluminum electrolytic capacitor shell according to claim 6, characterized in that: the distance between the limiting rod and the whole column of tracks is larger than the diameter of the shell of the aluminum electrolytic capacitor and smaller than the height of the shell of the aluminum electrolytic capacitor.

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