CN209905721U - Bottle cap directional feeding vibration disc - Google Patents

Abstract

The utility model discloses a directional feeding vibration disk for bottle caps, which comprises a vibration platform, a hopper, a spiral track and a discharge track; the side wall of the hopper is also provided with a detection mechanism, a steering track and a pushing mechanism which correspond to the discharge port of the spiral track; the detection mechanism comprises a sensor bracket and a depth sensor; the turning track comprises a turning section and a flow guiding section, wherein the turning section is provided with a horizontal downward necking slope, the bottle cap is gradually changed from a horizontal state to a vertical state through the necking slope, then the bottle cap is spirally transited to a cap opening downward-inclined state and finally transited to the horizontal state, and therefore the bottle cap is gradually changed from the upward cap opening to the downward cap opening in the downward conveying process. The utility model discloses a can realize all bottle lid all closing openings in the hopper and directional sequencing is carried down, has avoided the relapse feed back of bottle lid and the directional feed inefficiency and the wearing and tearing situation that leads to, has greatly improved feed efficiency.

Description

Bottle cap directional feeding vibration disc

Technical Field

The utility model relates to a directional feed vibrations dish of bottle lid.

Background

The vibration disc is used for orderly arranging the products for feeding to an automatic assembling machine or an automatic processing machine, so that all parts of the products are assembled into a complete product by matching with the automatic assembling machine, or the vibration disc is matched with the automatic processing machine to finish processing the workpieces.

On beverage encapsulation production line, need adopt the vibrations dish to produce the line and supply the bottle lid, and because the bottle is the bottleneck and moves up after filling with liquid, consequently need ensure that the vibrations dish makes the bottle lid in the exit all be in the apron and discharge in proper order of sequence down when supplying the bottle lid, make things convenient for follow-up robot to directly snatch like this or absorb the apron down bottle lid and directly aim at the bottleneck and screw up the encapsulation.

In the prior art, when the bottle caps are conveyed by the vibration disc, in order to ensure that the cap openings of the bottle caps at the outlet are downward, a sorting mode is generally adopted, namely, the bottle caps with the downward cap openings are passed through and used for subsequent packaging by a specific sorting mechanism, the bottle caps with the upward cap openings are sieved and returned to the hopper by a material pushing mechanism and the like for re-sorting and conveying, and due to the fact that the cap openings are downward probability events, the situations such as repeated material returning and the like can be caused, so that the feeding efficiency is low, and the bottle caps are easily abraded during repeated conveying.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a directional feeding vibration disc for bottle caps, which comprises a vibration table, a hopper arranged on the vibration table, a spiral track spirally arranged on the inner wall of the hopper, and a discharging track;

one end of the spiral track extends downwards to the bottom of the hopper in a spiral mode to serve as a feeding hole, the other end of the spiral track extends upwards to the top of the hopper in a spiral mode to serve as a discharging hole, and the feeding hole of the discharging track is communicated with the discharging hole of the spiral track;

the spiral guide rail has an inclination angle towards the hopper side wall so as to facilitate single sequencing conveying of bottle caps close to the hopper side wall; the horizontal plane of the discharge port of the discharge rail is lower than the horizontal plane of the feed port of the discharge rail so as to realize efficient sliding feeding of bottle caps, and the discharge port of the discharge rail is provided with a stop block for storing materials and facilitating material taking of a manipulator;

the side wall of the hopper is also provided with a detection mechanism corresponding to the position of the discharge hole of the spiral track, a steering track arranged on the side part of the spiral track and a material pushing mechanism corresponding to the inlet of the steering track, the feed inlet of the steering track is communicated with the spiral track, and the discharge hole of the steering track is communicated with the discharge track; the detection mechanism comprises a sensor bracket arranged on the hopper and a depth sensor arranged on the sensor bracket; the turning track comprises a turning section and a flow guide section, wherein the turning section is provided with a horizontal downward necking slope and a necking slope, so that the bottle cap is gradually changed from a horizontal state to a vertical state, then is spirally transited to a cover opening downward-inclined state and finally transits to the horizontal state, the bottle cap is gradually changed from the cover opening upwards to the cover opening downwards in the downward conveying process, and then the cover opening downward-facing bottle cap is used in the flow guide section to complete the collection of the discharge track by utilizing the horizontal height difference between the turning section feed inlet and the flow guide section discharge outlet.

Further, still be provided with the lift cylinder on the sensor support, degree of depth sensor installs on the lift cylinder to be used for the response of the bottle lid of the different degree of depth specifications.

Wherein, the depth sensor is any one of an infrared sensor, an acoustic wave sensor and a mandril sensor.

Wherein the discharging rail has a downward inclined angle alpha relative to the horizontal plane, and alpha is more than 0 degree and less than or equal to 30 degrees.

Furthermore, the discharge hole of the discharge rail is arranged to be a horizontal buffer section so as to avoid the bottle caps from being extruded mutually and to lead to the fact that the bottle caps at the front end are turned over when the materials are taken.

Through the technical scheme, the utility model is provided with the depth sensor to sense whether the cover opening of the bottle cap is upward, the bottle cap with the upward cover opening is pushed into the steering track through the material pushing mechanism, and the bottle cap with the downward cover opening directly enters the discharging track; the bottle caps with upward cap openings entering the turning track are gradually changed into a vertical state from a horizontal state through the necking gradient in the turning track, are transited to a cap opening downward inclined state through further spiral inclination of the necking gradient and finally transited to a horizontal state with downward cap openings, and then are converged into the discharging track to finish directional sequencing conveying. The utility model discloses can realize all bottle lid all the lid openings directional sequencing transport down in the hopper, avoid the relapse feed back of bottle lid and the directional feed inefficiency and the wearing and tearing situation that leads to, greatly improve feed efficiency.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly described below.

Fig. 1 is a schematic structural view of a directional feeding vibration plate for bottle caps disclosed in the embodiment of the present invention;

FIG. 2 is a partial schematic view of a turning section according to an embodiment of the present invention;

fig. 3 is a schematic side view of the flow guide section disclosed in the embodiment of the present invention.

The figures in the drawings represent:

10. vibrating table 20, hopper 30, spiral track

40. Discharge rail 51, sensor support 52, depth sensor

61. Turning section 62, flow guide section 63 and buffer section

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Example 1:

referring to fig. 1, the present invention provides a directional feeding vibration tray for bottle caps, which comprises a vibration table 10, a hopper 20 disposed on the vibration table 10, a spiral track 30 spirally disposed on the inner wall of the hopper 20, and a discharge track 40; one end of the spiral track 30 extends downwards to the bottom of the hopper 20 in a spiral manner to serve as a feeding hole, the other end of the spiral track 30 extends upwards to the top of the hopper 20 in a spiral manner to serve as a discharging hole, and the feeding hole of the discharging track 40 is communicated with the discharging hole of the spiral track 30; the spiral guide rails have an inclination angle towards the side wall of the hopper 20 so as to facilitate the single sequencing conveying of the bottle caps against the side wall of the hopper 20; the horizontal plane of the discharge port of the discharge rail 40 is lower than the horizontal plane of the feed port of the discharge rail 40 so as to realize efficient sliding feeding of bottle caps (referring to fig. 3, the discharge rail 40 has a downward inclined angle alpha relative to the horizontal plane, and alpha is more than 0 degree and less than or equal to 30 degrees; the discharge port of the discharge rail 40 is provided with a horizontal buffer section 63 so as to avoid turning over the bottle caps at the front end when the bottle caps are taken due to mutual extrusion, and a stop block is arranged at the discharge port of the discharge rail 40 for storing materials and facilitating taking materials by a manipulator; the side wall of the hopper 20 is also provided with a detection mechanism corresponding to the position of the discharge hole of the spiral track 30, a turning track arranged at the side part of the spiral track 30 and a material pushing mechanism corresponding to the inlet of the turning track, the feed inlet of the turning track is communicated with the spiral track 30, and the discharge hole is communicated with the discharge track 40; the detection mechanism comprises a sensor bracket 51 arranged on the hopper 20 and a depth sensor 52 arranged on the sensor bracket 51; referring to fig. 2, the turning track includes a turning section 61 and a diversion section 62, the turning section 61 has a horizontal downward necking slope, and the necking slope enables the bottle cap to gradually change from a horizontal state to a vertical state, then to spirally transition to a cover mouth downward-inclined state, and finally to a horizontal state, so that the bottle cap gradually changes from a cover mouth upward to a cover mouth downward in a downward conveying process, and then the bottle cap with the cover mouth downward finishes the collection to the discharging track 40 by using a horizontal height difference between a feeding port of the turning section 61 and a discharging port of the diversion section 62 in the diversion section 62.

Example 2:

based on above-mentioned embodiment 1, refer to fig. 1, still be provided with the lift cylinder on the sensor support 51, depth sensor 52 installs on the lift cylinder to be used for the response of the bottle lid of different degree of depth specifications. The depth sensor 52 is any one of an infrared sensor, an acoustic wave sensor, and a jack sensor.

The utility model is provided with a depth sensor 52 to sense whether the cover opening of the bottle cap is upward, the bottle cap with the upward cover opening is pushed into the steering track through the material pushing mechanism, and the bottle cap with the downward cover opening directly enters the discharging track 40; the bottle caps with upward caps entering the turning track are gradually changed into a vertical state from a horizontal state through the necking gradient in the turning track, are transited to a state that the caps are inclined downwards through further spiral inclination of the necking gradient and finally transited to a horizontal state that the caps are downward, and then are converged into the discharging track 40 to finish directional sequencing conveying. The utility model discloses can realize all bottle lid equal cover openings directional sequencing transport down in the hopper 20, avoid the relapse feed back of bottle lid and the directional feed inefficiency and the wearing and tearing situation that leads to, greatly improve feed efficiency.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to the above-described embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (5)

1. A directional feeding vibration disc for bottle caps comprises a vibration table (10), a hopper (20) arranged on the vibration table (10), a spiral track (30) spirally arranged on the inner wall of the hopper (20), and a discharge track (40);

one end of the spiral track (30) extends downwards to the bottom of the hopper (20) in a spiral mode to serve as a feeding hole, the other end of the spiral track (30) extends upwards in a spiral mode to the top of the hopper (20) to serve as a discharging hole, and the feeding hole of the discharging track (40) is communicated with the discharging hole of the spiral track (30);

the bottle cap sorting machine is characterized in that the spiral track has an inclination angle towards the side wall of the hopper (20) so as to facilitate the bottle caps to be tightly attached to the side wall of the hopper (20) for single sorting and conveying; the horizontal plane of the discharge hole of the discharge rail (40) is lower than the horizontal plane of the feed hole of the discharge rail (40) so as to realize efficient sliding feeding of bottle caps, and a stop block is arranged at the discharge hole of the discharge rail (40) and used for storing materials and facilitating material taking by a manipulator;

the side wall of the hopper (20) is also provided with a detection mechanism corresponding to the position of a discharge hole of the spiral track (30), a turning track arranged on the side part of the spiral track (30) and a material pushing mechanism corresponding to an inlet of the turning track, the feed hole of the turning track is communicated with the spiral track (30), and the discharge hole of the turning track is communicated with the discharge track (40); the detection mechanism comprises a sensor bracket (51) arranged on the hopper (20) and a depth sensor (52) arranged on the sensor bracket (51); the turning track comprises a turning section (61) and a flow guide section (62), wherein the turning section (61) is provided with a horizontal downward necking slope and a necking slope, so that the bottle cap is gradually changed from a horizontal state to a vertical state, then is spirally transited to a cover opening downward-inclined state and finally transited to the horizontal state, the bottle cap is gradually changed from the cover opening upwards to the cover opening downwards in the downward conveying process, and then the cover cap with the cover opening downwards is arranged on the flow guide section (62) by utilizing the horizontal height difference between the feeding hole of the turning section (61) and the discharge hole of the flow guide section (62) to complete the collection of the discharge track (40).

2. The bottle cap directional feed vibration plate of claim 1, characterized in that the sensor bracket (51) is further provided with a lifting cylinder, and the depth sensor (52) is mounted on the lifting cylinder for sensing bottle caps with different depth specifications.

3. A cap directional feed vibratory pan as claimed in claim 1 or claim 2 wherein the depth sensor (52) is any one of an infrared sensor, a sonic sensor and a ram sensor.

4. The cap orienting feed shaker pan of claim 1 wherein the discharge rail (40) has a downward slope angle α with respect to the horizontal, and 0 ° < α ≦ 30 °.

5. The vibratory plate for directional feeding of caps as claimed in claim 4, wherein the discharge port of the discharge rail (40) is configured as a horizontal buffer section to avoid the caps from being pushed against each other and thereby causing the caps to be turned over when the caps are taken from the front end.

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