CN219173551U - Multi-station rotary feeding mechanism - Google Patents

Abstract

The utility model relates to a multi-station rotary feeding mechanism, which comprises: the lower end of the vibration disc is provided with a first driving device connected through a first sliding rail, and the vibration disc can reciprocate on the first sliding rail; the material loading assembly comprises a first rotary table connected with a first rotary device, and a second rotary table is arranged on the circumference of the first rotary table; the material loading assembly is provided with a material loading station, and the end part of the direct vibration rail of the vibration disc is connected with the material loading station; and a friction rotating assembly is arranged below the material carrying station, and can drive the second turntable to rotate when the first turntable drives the second turntable to rotate the material carrying station. Through the design of carousel formula feed mechanism, the production facility of whole electronic product is compacter, reduces equipment area.

Description

Multi-station rotary feeding mechanism

Technical Field

The utility model relates to the technical field of feeding mechanisms, in particular to a multi-station rotary feeding mechanism.

Background

And when the electronic product is produced, the miniature electronic components are orderly and stably fed, and the basis of the subsequent processing procedures is adopted. The electronic product generally needs more miniature electronic components that use, and traditional miniature electronic components's material loading back is the linear type motion generally, and corresponding arm and equipment mechanism etc. arrange along its rectilinear motion's track both sides and set up, cause holistic production facility volume great, and the transmission mode of linear type, and the quantity of the electronic components of unit transmission is less, has failed to satisfy to the production of the electronic components of complex structure. Therefore, the utility model develops a multi-station rotary feeding mechanism to solve the problems in the prior art.

Disclosure of Invention

The utility model aims at: the utility model provides a rotatory feed mechanism of multistation to solve the problem such as whole equipment is great, unit material loading volume is less that leads to because of feed mechanism among the prior art.

The technical scheme of the utility model is as follows: a multi-station rotary feeding mechanism comprises:

the lower end of the vibration disc is provided with a first driving device connected through a first sliding rail, and the vibration disc can reciprocate on the first sliding rail;

the material loading assembly comprises a first rotary table connected with a first rotary device, and a second rotary table is arranged on the circumference of the first rotary table;

the material loading assembly is provided with a material loading station, and the end part of the direct vibration rail of the vibration disc is connected with the material loading station;

and a friction rotating assembly is arranged below the material carrying station, and can drive the second turntable to rotate when the first turntable drives the second turntable to rotate the material carrying station.

Preferably, the second turntables are arranged in a plurality and uniformly arranged on the circumference of the first turntables;

the first rotating disc is circumferentially provided with a first support, the first support is connected with the first rotating disc through a second sliding rail which is vertically arranged, the lower end of the second rotating disc is provided with a first vertical rotating shaft, and the first rotating shaft penetrates through the first support and can rotate on the first support.

Preferably, the friction rotating assembly comprises a second rotating device connected with the jacking cylinder, a friction disc is arranged at the upper end of the second rotating device, and the friction disc is connected with the lower end of the first rotating shaft and can drive the first rotating shaft to rotate through rotating friction.

Preferably, the second turntable is further connected with a speed reducing assembly, the speed reducing assembly comprises a fixed block, and the fixed block is provided with a speed reducing block connected with the second turntable in a penetrating manner.

Preferably, the first cylinder is arranged on the material carrying station, the pushing block is connected to the first cylinder, and when the second turntable rotates to the material carrying station, the first cylinder can push the deceleration block to be in abutting connection with the second turntable through the driving pushing block.

Preferably, a magnetic plate is disposed on the second turntable.

Compared with the prior art, the utility model has the advantages that:

(1) Through the design of the rotary table type feeding mechanism, the whole production equipment of the electronic product is more compact, and the occupied area of the equipment is reduced;

(2) The first rotating discs drive the plurality of second rotating discs, the second rotating discs rotate when the electronic components are fed, meanwhile, the vibrating discs reciprocate, a plurality of circles of products can be arranged on the second rotating discs, the loading bearing capacity is greatly improved, and the production efficiency is further improved;

(3) The rotation of the friction rotating assembly drives the second turntable to rotate through friction force, so that the connection is convenient, the rotating speed can be conveniently controlled, and the arrangement of electronic components is more dense.

Drawings

The utility model is further described below with reference to the accompanying drawings and examples:

FIG. 1 is a schematic structural view of a multi-station rotary feeding mechanism according to the present utility model;

FIG. 2 is a schematic view of a material loading assembly according to the present utility model;

FIG. 3 is an enlarged schematic view of the structure of FIG. 2A;

fig. 4 is a schematic structural view of the friction rotating assembly according to the present utility model.

Wherein: a vibration disk 1, a first driving device 11, a first sliding rail 12 and a direct vibration rail 13;

the device comprises a loading assembly 2, a loading station 2a, a first rotating device 21, a first rotating disc 22, a second rotating disc 221, a magnetic plate 222, a first bracket 223, a second sliding rail 224, a first rotating shaft 225, a speed reducing assembly 23, a fixed block 231 and a speed reducing block 232;

a friction rotating assembly 3, a lifting cylinder 31, a friction disk 32, and a second rotating device 33;

the first cylinder 4, the push block 41.

Detailed Description

The following describes the present utility model in further detail with reference to specific examples:

as shown in fig. 1 to 4, a multi-station rotary feeding mechanism includes: the vibration dish 1, vibration dish 1 lower extreme is provided with the first drive arrangement 11 that is connected through first slide rail 12, and vibration dish 1 can reciprocate on first slide rail 12.

In the embodiment, the straight vibration rail 13 of the vibration disk 1 is obliquely arranged, and the position of the discharge end of the straight vibration rail is lower than that of the feed end; the discharging end is positioned at the material loading station 2a and above the second rotary table 221; the microelectronic components can fall onto the magnetic plate 222 on the second turntable 221 through the direct vibration track 13, and are magnetically adhered by the magnetic plate 222.

The first driving means 11 may be a cylinder, a servo motor, etc.

The material loading assembly 2, the material loading assembly 2 comprises a first rotating disc 22 connected with the first rotating device 21, a second rotating disc 221 is arranged on the circumference of the first rotating disc 22, and a magnetic plate 222 is arranged on the second rotating disc 221; wherein, the material loading assembly 2 is provided with a material loading station 2a, and the end part of the direct vibration rail 13 of the vibration disc 1 is connected with the material loading station 2 a; a friction rotating assembly 3 is arranged below the material loading station 2a, and when the first turntable 22 drives the second turntable 221 to rotate the material loading station 2a, the friction rotating assembly 3 can drive the second turntable 221 to rotate.

The circumference of the first rotating disc 22 is provided with a first support 223, the first support 223 is connected with the first rotating disc 22 through a second sliding rail 224 which is vertically arranged, the lower end of the second rotating disc 221 is provided with a first vertical rotating shaft 225, and the first rotating shaft 225 penetrates through the first support 223 and can rotate on the first support 223.

The friction rotating assembly 3 comprises a second rotating device 33 connected with the jacking cylinder 31, a friction disc 32 is arranged at the upper end of the second rotating device 33, the friction disc 32 is connected with the lower end of the first rotating shaft 225, and the first rotating shaft 225 can be driven to rotate through rotating friction.

In the present embodiment, the number of the second rotating discs 221 is four, but a plurality of second rotating discs can be set according to actual production requirements; four second rotary discs 221 are arranged uniformly on the circumference of the first rotary disc 22.

When the first rotating device 21 drives the first rotating disc 22 to rotate, so that the second rotating disc 221 rotates to the loading station 2a, the jacking cylinder 31 drives the second rotating device 33 to move upwards obliquely to the friction disc 32 to jack up the first rotating shaft 225, the first rotating shaft 225 supports the second rotating disc 221 to move upwards, so that the magnetic plate 222 approaches to the discharge hole of the direct vibrating track 13, and position or state change caused by overturning and the like due to overlarge distance in the process of discharging the micro electronic components into the magnetic plate 222 is avoided; the second rotating device 33 drives the friction disc 32 to rotate, and drives the first rotating shaft 225 to rotate through the friction force between the friction disc 32 and the first rotating shaft 225, so that the second rotating disc 221 and the magnetic plate 222 rotate; the micro electronic components can be circumferentially arranged on the magnetic plate 222, and meanwhile, the first driving device 11 drives the vibration disk 1 to move, so that the discharge hole of the direct vibration track 13 moves towards the outer ring of the magnetic plate 222, and the micro electronic components are spirally circumferentially arranged on the magnetic track.

The first rotating device 21 and the second rotating device 33 may be a rotating cylinder, a rotating motor, or other devices capable of driving rotation; when the second rotary table 221 rotates to the loading station 2a, the rotation axes of the first rotary shaft 225 and the friction plate 32 are coincident, so as to ensure stable rotation of the second rotary table 221.

The second turntable 221 is further connected with a speed reducing assembly 23, the speed reducing assembly 23 comprises a fixed block 231, and a speed reducing block 232 connected with the second turntable 221 is arranged on the fixed block 231 in a penetrating mode.

The material loading station 2a is provided with a first air cylinder 4, the first air cylinder 4 is connected with a push block 41, and when the second rotary table 221 rotates to the material loading station 2a, the first air cylinder 4 can push the speed reducing block 232 to be in abutting connection with the second rotary table 221 by driving the push block 41.

In this embodiment, the first cylinder 4 is not provided on the first rotary disk 22, but on another support structure (not shown in the drawings); the speed reducing assemblies 23 are arranged corresponding to the second turntables 221, namely, each second turntable 221 is correspondingly provided with one speed reducing assembly 23; when the second rotary table 221 rotates to the loading station 2a, the push block 41 is just positioned at one side of the deceleration block 232 away from the second rotary table 221; when the second rotary table 221 is lifted up by the friction rotary assembly 3 to prepare for loading, the circumferential wall of the second rotary table 221 is located at the speed reducing block 232, so that the speed reducing block 232 can be pushed by the pushing block 41 to abut against the second rotary table 221, and the purpose of controlling the rotation speed of the second rotary table 221 is achieved.

The friction speed reducing assembly 23 is designed, so that the situation that the micro electronic components are thrown out and the like due to the fact that the rotating speed of the rotating disc is too high is effectively avoided.

The above embodiments are only for illustrating the technical concept and features of the present utility model, and are intended to enable those skilled in the art to understand the content of the present utility model and implement the same according to the content of the present utility model, and are not intended to limit the scope of the present utility model. It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments and that the present utility model may be embodied in other specific forms without departing from the spirit or essential attributes thereof, and it is therefore desired that the present utility model be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims (6)

1. Multi-station rotary feeding mechanism, its characterized in that includes:

the lower end of the vibration disc is provided with a first driving device connected through a first sliding rail, and the vibration disc can reciprocate on the first sliding rail;

the material loading assembly comprises a first rotary table connected with a first rotary device, and a second rotary table is arranged on the circumference of the first rotary table;

the material loading assembly is provided with a material loading station, and the end part of the direct vibration rail of the vibration disc is connected with the material loading station;

and a friction rotating assembly is arranged below the material carrying station, and can drive the second turntable to rotate when the first turntable drives the second turntable to rotate the material carrying station.

2. The multi-station rotary feeding mechanism according to claim 1, wherein: the second turntables are arranged in a plurality and uniformly arranged on the circumference of the first turntables;

the first rotating disc is circumferentially provided with a first support, the first support is connected with the first rotating disc through a second sliding rail which is vertically arranged, the lower end of the second rotating disc is provided with a first vertical rotating shaft, and the first rotating shaft penetrates through the first support and can rotate on the first support.

3. The multi-station rotary feeding mechanism according to claim 2, wherein: the friction rotating assembly comprises a second rotating device connected with the jacking air cylinder, a friction disc is arranged at the upper end of the second rotating device, and the friction disc is connected with the lower end of the first rotating shaft and can drive the first rotating shaft to rotate through rotating friction.

4. The multi-station rotary feeding mechanism according to claim 2, wherein: the second turntable is also connected with a speed reducing assembly, the speed reducing assembly comprises a fixed block, and the fixed block is provided with a speed reducing block connected with the second turntable in a penetrating way.

5. The multi-station rotary feeding mechanism according to claim 4, wherein: the first cylinder is arranged on the material carrying station, the pushing block is connected to the first cylinder, and when the second turntable rotates to the material carrying station, the first cylinder can push the deceleration block to be in abutting connection with the second turntable through the driving pushing block.

6. The multi-station rotary feeding mechanism according to claim 1, wherein: and a magnetic plate is arranged on the second turntable.

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