WO2018103261A1 - Bottle turning device - Google Patents

Abstract

A bottle turning device, comprising discharge turning tracks (40); the inlet ends of the discharge turning tracks (40) are communicated with the discharge openings (101) or exit ends of the discharge sliding tracks (151); the outlet ends of the discharge turning tracks (40) are communicated with hollow bubble caps (70) or a bottle conveyor track; the discharge turning tracks (40) correspond to bottles (50) in shape; the discharge turning tracks (40) gradually turn from the inlet ends to the outlet ends; the bottles (50) can be gradually turned along with the turning of the discharge turning tracks (40) in a falling process passing through the discharge turning tracks (40), so that the bottles can fall into the hollow bubble caps (70) or onto the bottle conveyor track at a proper angle.

Description

Bottle steering device Technical field

The present invention relates to a delivery device, and more particularly to a bottle steering device.

Background technique

The traditional bottle conveying device is to lay the bottle on the conveyor belt, rotate the belt by the motor to transport the bottle, and finally push the bottle into the blanking slide and fall into the empty bubble cover or the bottle conveying track. . However, in order to cause the bottle to fall into the empty blister or bottle transport track in a predetermined orientation, it is usually necessary to set the orientation of the empty blister or bottle transport track depending on the orientation of the bottle, which will add technical difficulty to the worker.

Summary of the invention

Based on this, it is necessary to provide a bottle steering device that allows the bottle to be conveyed in a predetermined direction to the empty blister or bottle conveying track in view of the deficiencies of the prior art.

The technical solution is as follows: a bottle steering device, comprising: a blanking track, the feeding end of the blanking track is used for communicating with the feeding port, and the discharging end of the material is used for the discharging end of the material Connected to the empty blister or bottle conveyor track; the blanking track is correspondingly shaped to the shape of the bottle, and the blanking track is gradually twisted from the feed end to the discharge end.

In the above-mentioned bottle steering device, the bottle can be gradually turned along with the twisting of the unloading turning track during the falling of the bottle through the unloading turning track. For example, the torsion angle of the feed end and the discharge end of the unloading steering rail is 90 degrees, so that after the bottle is discharged, it can be turned 90 degrees in the horizontal direction, so that it can fall into the empty bubble or bottle conveying track at a suitable angle. on.

In one embodiment, the blanking track is a plurality of, and the plurality of blanking tracks are arranged side by side.

In one embodiment, the bottle steering device further includes a reverse feeding mechanism, the reverse feeding mechanism includes a blanking plate, a limiting baffle, a switch plate and a first driving mechanism; The limiting baffle is located above the lowering plate, and one end of the limiting baffle projected on the lowering plate is located at an edge of the lowering opening, Between the limiting baffle and the blanking plate, the spacing is larger than the outer diameter of the bottle head and smaller than the outer diameter of the bottle tail; the switch plate corresponds to the lowering opening Providing that the first driving mechanism is configured to drive the switch board to move in or out of the discharge port; when the limit baffle is in contact with the bottle head, the bottle tail is completely located on the switch board Above; when the limiting baffle abuts the tail of the bottle, a portion of the bottle head protrudes out of the lower opening and above the lowering plate. When the first driving mechanism drives the switch board to be removed from the stocking opening, if the head of the bottle is flattened forward, the head of the bottle is located between the limiting baffle and the lowering plate, so that the head of the bottle can not be hung by the lowering plate. Flip, and the tail of the bottle is completely in the lower opening. Due to the loss of the support of the switchboard, a 90-degree flip occurs and falls into the blanking channel; if the tail of the bottle is flattened forward, a part of the head of the bottle protrudes. Outside the lower opening and above the lowering plate, the bottom of the bottle can not be turned over, and the tail of the bottle cannot extend into the space between the limiting baffle and the lowering plate due to the interference limit baffle. It is completely located in the lower feed port, and due to the loss of the support of the switch plate, it will turn 90 degrees and fall into the blanking channel. Thus, regardless of whether the bottle in the transport track is lying flat or lying flat, this embodiment enables the bottle to fall into the empty blister or bottle transport track in the same orientation, resulting in higher work efficiency.

In one embodiment, the bottle steering device further includes a partitioning mechanism disposed above the lowering plate, and the partitioning mechanism is slidably engaged with the lowering plate, the separating mechanism Include a plurality of first partition blocks arranged side by side, adjacent to the first partition block The interval between the two can be used for the bottle to pass through; the blanking plate is provided with an opening area, and the switch plate is plural, and the switch plate and the limiting baffle are adjacent to the first one. Corresponding to the interval between the partitioning blocks, the switch plates are arranged side by side in the open area, the switch plate is connected to the lower material plate, and the lower feed port is located between adjacent switch plates . In this embodiment, the switch board and the lower board are integrally formed, and the limit baffle is mounted on the partition mechanism. The plurality of lying bottles may be separated from each other by the plurality of first partitioning blocks, and the lower driving plate is driven to slide relative to the partitioning mechanism by the first driving mechanism to control whether the interval between the adjacent first separating blocks is Whether the spacing between the adjacent switch plates is in communication, if they are connected, the bottles in the interval between adjacent first partition blocks fall into the blanking passage through the feeding port, and if they are not connected, the bottle can be Slide forward on the switch board and eventually interfere with the limit stop.

In one embodiment, the bottle steering device further includes a blanking partition, the blanking separator is disposed below the lowering panel, and the blanking separator comprises a side by side arrangement a plurality of blanking chutes, wherein the unloading chutes correspond to the intervals between adjacent ones of the first separating blocks. After the bottle falls from the blanking port, it enters the blanking chute of the blanking partition and slides down through the blanking slide. The unloading chute is the sliding track of the bottle, which prevents the bottle from turning over and ensures that the tail of the bottle slides down to the empty blister or bottle conveying track. In this embodiment, the blanking partition plate is inclined by 80 to 85 degrees with respect to the lowering plate, so that the bottle runs downward along the bottom wall of the blanking slide during the blanking process of the bottle.

In one embodiment, the bottle steering device further includes a carrier plate and a transport bottle mechanism, the carrier plate is juxtaposed with a plurality of chutes for the bottle to slide, the chute and the first partition The spacing between the stops corresponds one by one, and the delivery bottle mechanism is used to drive the bottles in the chute to the blanking plate. In this embodiment, the bottle mechanism includes a rotating shaft disposed above the carrier, and a push plate disposed on the rotating shaft. The rotation of the rotating shaft drives the push plate to rotate, so that the bottle on the carrier plate can be knocked down from the standing state to the flat state, and the flat bottle can be pushed out. Carrier output. In this way, work efficiency can be improved without the need for a manual manual bottle pouring operation. In this embodiment, the bottle to be delivered is a flat bottle, and the width of the flat bottle is larger than the thickness of the flat bottle. The width of the chute is designed corresponding to the thickness of the bottle, and the depth of the chute is less than the width of the bottle. In this way, after the bottle is pushed into the chute, the bottle still protrudes out of the chute of the carrier plate, and the push plate can contact the bottle outside the chute during the rotation of the rotating shaft, and is pushed along the plate. The carrier plate is pushed out in the direction of the chute. In this embodiment, the push plates are two or more, the push plates are disposed along an axial direction of the rotating shaft, and the push plates are spaced apart from the outer side walls of the rotating shaft. And the push plate is an elastic plate. The outer side wall of the rotating shaft is provided with a card slot, and the push plate is fixed in the card slot. The push plate is made of silicone material. In this way, the push plate can be prevented from damaging the bottle during the process of knocking down the bottle.

In one embodiment, the bottle steering device further includes a vibration mechanism coupled to the carrier plate.

In one embodiment, the bottle steering device further includes a first side fence and a second side fence, and the first side fence and the second side fence are respectively disposed on the carrier On both sides.

In one embodiment, the bottle steering device further includes a first end baffle and a second end baffle, the first end baffle being disposed at a bottle output end of the carrier, the first end a distance between a bottom surface of the baffle and the bottom wall of the chute is smaller than a height of the bottle; the second end baffle is disposed on the carrier, and the second end baffle and the first end The baffles are disposed opposite to each other, and the first end baffle, the second end baffle, the first side baffle and the second side baffle enclose a silo. In this way, the bottle in the standing state is blocked by the first end flap, and the bottle in the standing state is prevented from being output. Since the first end baffle, the second end baffle, the first side baffle and the second side baffle enclose the silo, the silo can limit the bottle to the carrier during the vibration of the bottle to avoid the vibration mechanism The bottle is shaken out or pushed out of the carrier during the vibrating bottle or during the push-down of the bottle.

In one embodiment, the bottle steering device further includes a bottle position control mechanism, The bottle position control mechanism includes a support plate, a switching partition plate and a second driving mechanism, the support plate is disposed between the carrier plate and the partitioning mechanism, and the switching partition plate is slidably engaged with the supporting plate. The switching partition is juxtaposed with a plurality of passages, the passages are correspondingly arranged with the chute; the second driving mechanism is configured to drive the switching partition to move to the first position or the second position, when When the second driving mechanism drives the switching baffle to move to the first position, the channel communicates with the chute, and the channel is disconnected from the interval between the adjacent first blocking blocks; When the second driving mechanism drives the switching partition to move to the second position, the channel is disconnected from the chute, and the interval between the channel and the adjacent first blocking block Connected. In this embodiment, the length of the passage in the switching partition corresponds to the length of the bottle, and when the bottle is completely moved into the passage in the switching partition, the switching partition is driven by the second driving mechanism to slide from the first position to the second position. When the channel is disconnected from the chute and the channel is in communication with the spacing between adjacent first dividing blocks, the bottle continues to move from the channel to the space between adjacent first dividing blocks. In this embodiment, the bottle steering device further includes a beam, the beam is disposed on the support plate, the beam is provided with a guide rail, the switching partition is provided with a slider, and the slider and the slider The rails slide fit.

DRAWINGS

1 is a schematic view of a material turning steering track in a bottle turning and unloading device according to an embodiment of the present invention;

2 is a schematic view showing an angle of a bottle turning and unloading device according to an embodiment of the present invention;

3 is a schematic view showing another angle of the bottle turning and unloading device according to the embodiment of the present invention;

4 is a schematic view showing a further angle of the bottle turning and unloading device according to the embodiment of the present invention, and having a blanking partition plate;

5 is a schematic view of a blanking plate in a bottle turning and unloading device according to an embodiment of the present invention;

6 is a schematic view of a flat bottle head against a limit baffle in a bottle inverting and unloading device according to an embodiment of the present invention;

Figure 7 is a schematic view 1 of the bottle reversing device in the embodiment of the present invention, in which the lying bottle is dropped from the feeding opening to the blanking passage;

FIG. 8 is a schematic view of the tail end of the bottle in the bottle turning and unloading device according to the embodiment of the present invention;

FIG. 9 is a second schematic view of the bottle lying in the bottle turning and unloading device according to the embodiment of the present invention, which is dropped from the feeding opening to the cutting channel;

10 is a schematic view showing a state in which a switching partition is located at a first position in a bottle turning and unloading device according to an embodiment of the present invention;

11 is a schematic view showing a state in which a switching partition is located at a second position in a bottle turning and unloading device according to an embodiment of the present invention;

12 is a schematic view showing a state in which a switching partition plate is again located at a first position in a bottle turning and unloading device according to an embodiment of the present invention;

13 is a schematic structural view 1 of a carrier plate and a vibration mechanism in a bottle turning and unloading device according to an embodiment of the present invention;

14 is a second schematic structural view of a carrier plate and a vibration mechanism in a bottle inverting and unloading device according to an embodiment of the present invention;

15 is a schematic view showing a steel spring of a vibration mechanism in a bottle turning and unloading device according to an embodiment of the present invention;

16 is a schematic view showing a spring of a vibration mechanism of a vibrating mechanism in a bottle turning and unloading device according to an embodiment of the present invention.

10, the cutting board, 101, the feeding port, 11, the limit baffle, 12, the switch board, 13, the first drive Mechanism, 14, partitioning mechanism, 141, first partitioning block, 142, spacing, 15, blanking partition, 151, blanking slide, 161, support plate, 162, switching partition, 163, second drive Mechanism, 164, channel, 165, slider, 17, beam, 171, guide rail, 18, blanking channel, 20, carrier board, 201, chute, 21, conveying bottle mechanism, 211, rotating shaft, 212, push plate , 22, first side baffle, 23, second side baffle, 24, first end baffle, 25, second end baffle, 26, silo, 27, frame, 28, drive motor, 30, Vibration mechanism, 31, base, 321, first steel spring, 322, second steel spring, 33, electromagnet, 34, iron core, 35, first mount, 36, second mount, 37, third Mounting seat, 38, fourth mounting seat, 39, base, 391, elastic block, 40, unloading steering track, 50, bottle, 60, speed control device, 70, blister.

detailed description

The embodiments of the present invention are described in detail below:

As shown in FIG. 1, a bottle steering device according to the present invention includes a material turning track 40. The feeding end of the unloading turning rail 40 communicates with the discharging port 101 or communicates with the outlet end of the blanking chute 151, and the discharging end of the unloading turning rail 40 communicates with the empty bubble cover 70 or the bottle conveying track. on. The blanking track 40 is disposed corresponding to the shape of the bottle 50 (as in Figures 6 and 8), and the blanking track 40 is gradually twisted from the feed end to the discharge end.

In the above-described bottle steering device, the bottle 50 can be gradually turned along with the twist of the unloading turning track 40 during the falling of the bottle turning rail 40. For example, when the feeding end and the discharging end of the feeding steering rail 40 have a twist angle of 90 degrees, the bottle 50 can be turned 90 degrees in the horizontal direction after being discharged, so that it can fall into the empty bubble cover 70 at a suitable angle or The bottle is transported on the track.

Referring to Figures 2-4, the bottle steering device further includes a flipping mechanism. The turning and unloading mechanism includes a lowering plate 10, a limiting baffle 11, a switch plate 12 and a first driving mechanism 13.

Referring to FIGS. 5-9 , the lower opening 101 is disposed on the lowering plate 10 . The limiting baffle 11 is located above the lowering plate 10, and one end of the limiting baffle 11 projected on the lowering plate 10 is located at an edge of the lowering opening 101. The margin of the end of the limiting baffle 11 at the edge of the lowering opening 101 can be set according to the actual situation, as long as the head can be reversely inverted, the limiting baffle 11 will not hinder the flat lying. The flipping action of the bottle 50 is sufficient. The limit baffle 11 and the lowering plate 10 are spaced apart from each other. The spacing is greater than the outer diameter of the head of the bottle 50 and less than the outer diameter of the tail of the bottle 50. In this embodiment, the outer diameter of the head of the bottle 50 is larger than the outer diameter of the tail of the bottle 50, that is, if the tail of the bottle 50 is lying flat forwardly above the lower opening 101 of the lowering plate 10, the tail of the bottle 50 is in contact with the limit baffle. 11. The forward movement cannot be continued. If the head of the bottle 50 is flattened forwardly into the lower opening 101 of the lowering plate 10, the head of the bottle 50 passes between the limiting baffle 11 and the lowering plate 10. The interval is blocked by the limit baffle 11 to prevent the forward movement. The switch board 12 is disposed corresponding to the discharge port 101, and the first drive mechanism 13 is configured to drive the switch board 12 to move into or out of the discharge port 101. When the limiting baffle 11 abuts the head of the bottle 50, the tail of the bottle 50 is completely above the switch board 12; when the limit baffle 11 abuts the tail of the bottle 50, A portion of the head of the bottle 50 protrudes out of the lower opening 101 and above the lowering plate 10.

When the first driving mechanism 13 drives the switch plate 12 to be removed from the cutting opening 101, if the head of the bottle 50 is lying flat forward, the head of the bottle 50 is located between the limiting baffle 11 and the lowering plate 10, such that the bottle 50 The head hanging plate 10 cannot be turned over, and the tail of the bottle 50 is completely located in the lower opening 101. Due to the loss of the support of the switch plate 12, a 90 degree inversion occurs and falls into the blanking channel 18; When the tail is flattened forward, a portion of the head of the bottle 50 protrudes out of the lower opening 101 and above the lowering plate 10, so that the head of the bottle 50 is caught by the lowering plate 10 and cannot be turned over, and the tail of the bottle 50 is The interference limit baffle 11 cannot extend into the interval between the limit baffle 11 and the lowering plate 10, and is finished. All are located in the lower opening 101, and due to the loss of the support of the switchboard 12, a 90 degree flip occurs and falls into the blanking channel 18. Thus, regardless of whether the bottle 50 in the transport track is lying flat or lying flat, this embodiment enables the bottle 50 to fall into the empty blister 70 or the bottle transport track in the same orientation, resulting in higher work efficiency.

Wherein, the bottle steering device further comprises a partitioning mechanism 14. The partitioning mechanism 14 is disposed above the lowering plate 10, and the partitioning mechanism 14 is slidably engaged with the lowering plate 10. The partition mechanism 14 includes a plurality of first partition blocks arranged side by side. An interval 142 between adjacent first partition stops 141 can be used for the bottle 50 to pass through. The lowering plate 10 is provided with an open area. The switch board 12 has a plurality of switch boards 12 and the limit baffle 11 respectively corresponding to the interval 142 between the adjacent first partition stops 141. The switch boards 12 are juxtaposed in the open area, and the switch board 12 is connected to the lower board 10. The feed opening 101 is located between adjacent switch plates 12. In one of the embodiments, the switch plate 12 is integrally formed with the lower plate 10, and the limit baffle 11 is mounted on the partition mechanism 14. The plurality of lying bottles 50 may be separated from each other by the plurality of first partitioning blocks 141, and the lowering plate 10 is driven to slide relative to the partitioning mechanism 14 by the first driving mechanism 13 to control the adjacent first separating blocks. Whether the interval 142 between the 141 is in communication with the interval between the adjacent switch plates 12, if communicated, the bottle 50 in the space 142 between the adjacent first partition blocks 141 is dropped into the blank through the feed port. In the passage 18, if not communicated, the bottle 50 can slide forward on the switch plate 12 and eventually interfere with the limit stop 11.

The bottle steering device further includes a blanking partition plate 15. The blank partitioning plate 15 is disposed below the lowering plate 10, and the blanking partitioning plate 15 includes a plurality of blanking chutes 151 arranged in parallel. The blanking chute 151 has a one-to-one correspondence with the interval 142 between the adjacent first partitioning blocks 141. After the bottle 50 is dropped from the discharge opening 101, it enters the blanking chute 151 of the blanking partitioning plate 15, and slides downward through the blanking chute 151. The cutting chute 151 is a sliding track of the bottle 50. It prevents the bottle from turning over and ensures that the end of the bottle 50 slides down to the empty bubble cover 70 or the bottle conveyor track. In the present embodiment, the blank partitioning plate 15 is inclined by 80 to 85 degrees with respect to the lowering plate 10, so that the bottle 50 runs downward along the bottom wall of the blanking slide 151 during the blanking process.

Referring to FIG. 13 and FIG. 14 , in the embodiment, the bottle steering device further includes a carrier 20 and a transport bottle mechanism 21 . A plurality of sliding slots 201 for the bottle 50 to slide over are arranged side by side on the carrier 20 . The interval between the chute 201 and the first partition block 141 is one-to-one. The bottle mechanism 21 is used to drive the bottle 50 in the chute 201 to the lowering plate 10. In the embodiment, the bottle mechanism 21 includes a rotating shaft 211 disposed above the carrier 20, and a push plate 212 disposed on the rotating shaft 211. The rotation of the rotating shaft 211 drives the push plate 212 to rotate, so that the bottle 50 on the carrier 20 can be knocked down from the standing state to the flat state, and the flat bottle 50 can be pushed out of the carrier 20 output. In this way, work efficiency can be improved without the need for a manual manual bottle pouring operation. In this embodiment, the bottle 50 to be conveyed is a flat bottle, and the width of the flat bottle is larger than the thickness of the flat bottle. The width of the chute 201 is designed corresponding to the thickness of the bottle 50, and the depth of the chute 201 is smaller than the width of the bottle 50. Thus, after the bottle 50 is pushed into the chute 201, the bottle 50 still partially protrudes out of the chute 201 of the carrier 20. During the rotation of the rotating shaft 212, the push plate 212 can contact the portion of the bottle 50 outside the sliding slot 201, and the pushing plate 212 pushes the carrier 20 in the direction of the sliding slot 201. In this embodiment, the push plates 212 are two or more, the push plates 212 are disposed along the axial direction of the rotating shaft 211, and the push plates 212 are spaced apart from the outer side walls of the rotating shaft 211. And the push plate 212 is an elastic plate. The outer side wall of the rotating shaft 211 is provided with a card slot, and the push plate 212 is locked in the card slot. The push plate 212 is a silicone material. Thus, during the process of pushing the bottle 212 down the bottle 50, damage to the bottle 50 can be avoided.

The bottle steering device further includes a first side baffle 22 and a second side baffle 23. The first side baffle 22 and the second side baffle 23 are respectively disposed on two sides of the carrier 20 .

The bottle steering device further includes a first end stop 24 and a second end stop 25. The first end baffle 24 is disposed at the bottle output end of the carrier 20, and the distance between the bottom surface of the first end baffle 24 and the bottom wall of the chute 201 is smaller than the height of the bottle 50. The second end stop 25 is disposed on the carrier 20, and the second end stop 25 is disposed opposite the first end stop 24. The first end stop 24 , the second end stop 25 , the first side baffle 22 and the second side baffle 23 enclose a silo 26 . Thus, the bottle 50 in the standing state is blocked by the first end stop 24 to avoid the output of the bottle 50 in the standing state. Since the first end baffle 24, the second end baffle 25, the first side baffle 22 and the second side baffle 22 enclose the silo 26, the silo 26 can limit the bottle 50 during the vibration of the bottle 50. On the carrier 20, the bottle 50 is oscillated or pushed out of the carrier 20 during the process of vibrating the bottle 50 by the vibrating mechanism 30 or during the knocking of the bottle 50 by the push plate 212.

In the embodiment, the bottle steering device further includes a vibration mechanism 30. The vibration mechanism 30 is drivingly coupled to the carrier 20 . The vibration mechanism 30 drives the carrier 20 to vibrate according to a preset frequency, which can facilitate the vibration of the bottle 50 on the carrier 20 and facilitate the vibration of the bottle 50 in the flat state, thereby facilitating the bottle on the carrier 20. 50 fast output. This ensures that the bottle 50 is smoothly discharged from the chute 201 on the carrier 20 to the discharge opening 101 of the lowering plate 10. Moreover, both the carrier 20 and the lowering plate 10 are slightly inclined by 5 to 20 degrees with respect to the horizontal plane, so that the vibration of the vibrating mechanism 30 can be made along the interval between the chute 201 and the first separating block 141 during the vibration of the vibrating mechanism 30. The 142 moves forward to the discharge port 101.

Referring to FIG. 15 and FIG. 16, the vibration mechanism 30 includes a base 31, a steel spring, an electromagnet 33, a core 34, and a control module for controlling whether the electromagnet 33 is energized. One end of the steel spring is connected to the base 31, and the other end of the steel spring is connected to the carrier 20. The electromagnet 33 and the iron core 34 are respectively disposed on the base 31 and the carrier 20, and the electromagnet 33 is disposed opposite to the core 34. The control module controls whether the electromagnet 33 is energized to generate a week With the magnetic force, the electromagnet 33 repeatedly attracts the iron core 34 under the action of the periodic magnetic force, thereby generating a periodic vibration phenomenon. The steel spring includes a first steel spring 321 and a second steel spring 322. The electromagnet 33 and the iron core 34 are located between the first steel spring 321 and the second steel spring 322. In this embodiment, the steel spring is plate-shaped or spiral. Thus, during the repeated suction and extraction of the electromagnet 33 and the iron core 34, the first steel spring 321 and the second steel spring 322 are simultaneously deformed by bending to generate a vibration phenomenon, and the vibration effect of the carrier 20 as a whole can be improved. In one embodiment, the vibration mechanism 30 further includes a first mount 35, a second mount 36, a third mount 37, and a fourth mount 38. One end of the steel spring is mounted on the base 31 through the first mounting seat 35, and the other end of the steel spring is mounted on the carrier 20 through the second mounting seat 36. The electromagnet 33 is mounted on the base 31 via the third mount 37, and the core 34 is mounted on the carrier 20 via the fourth mount 38. In this embodiment, the first mounting seat 35, the second mounting seat 36, the third mounting seat 37, and the fourth mounting seat 38 are all L-shaped plates. In one of the embodiments, the bottle steering device further includes a base 39. The base 39 is disposed under the base 31, and an elastic block 391 is disposed between the base 39 and the base 31. The additional elastic block 391 makes the vibration effect of the carrier 20 more obvious.

Referring to FIG. 2 and FIG. 4 again, in one embodiment, the bottle steering device further includes a bottle position control mechanism. The bottle position control mechanism includes a support plate 161, a switching partition 162, and a second driving mechanism 163. The support plate 161 is disposed between the carrier plate 20 and the partition mechanism 14 , and the switchboard 162 is slidably engaged with the support plate 161 . The switching partitions 162 are juxtaposed with a plurality of passages 164, and the passages 164 are disposed one by one corresponding to the sliding slots 201. The second driving mechanism 163 is configured to drive the switching partition 162 to move to a first position or a second position. Referring to FIGS. 10-12, when the second driving mechanism 163 drives the switching partition 162 to move to the first position, the passage 164 is in communication with the chute 201, and the passage 164 is adjacent to The first The interval 142 between the partitioning blocks 141 is disconnected; when the second driving mechanism 163 drives the switching partition 162 to move to the second position, the passage 164 is disconnected from the chute 201, and The passage 164 is in communication with an interval 142 between adjacent first partition stops 141. In the present embodiment, the length of the passage 164 in the switching partition 162 corresponds to the length of the bottle 50. When the bottle 50 is completely moved into the passage 164 in the switching partition 162, the switching partition 162 is driven by the second driving mechanism 163. The first position slides to the second position, at which time the passage 164 is disconnected from the chute 201 and the passage 164 is in communication with the spacing 142 between the adjacent first partition stops 141, and the bottle 50 continues to move from the passage 164 to In the interval 142 between adjacent first partition stops 141.

The bottle steering device also includes a beam 17. The beam 17 is disposed on the support plate 161, and the beam 17 is provided with a guide rail 171. The switching partition 162 is provided with a slider 165 that is slidably engaged with the guide rail 171.

Referring to FIG. 13 and FIG. 14 again, in the embodiment, the bottle steering device further includes a speed control device 60. The speed control device 60 is electrically connected to the vibration mechanism 30 or the bottle mechanism 21, and the speed control device 60 is used to adjust the vibration frequency of the vibration mechanism 30 or to adjust the bottle mechanism 21 The speed of the bottle. In this embodiment, the bottle mechanism 21 includes a drive motor 28, and a torque output shaft of the drive motor 28 is drivingly coupled to the rotation shaft 211. In this embodiment, the driving motor 28 and the speed control device 60 are disposed on the first side baffle 22 or the second side baffle 23 or the first side baffle 22 and the second side baffle 23 On the rack 27.

The technical features of the above-described embodiments may be arbitrarily combined. For the sake of brevity of description, all possible combinations of the technical features in the above embodiments are not described. However, as long as there is no contradiction between the combinations of these technical features, All should be considered as the scope of this manual.

The above-described embodiments are merely illustrative of several embodiments of the present invention, and the description thereof is more specific and detailed, but is not to be construed as limiting the scope of the invention. It should be noted that for this A person skilled in the art can make several modifications and improvements without departing from the spirit and scope of the invention. Therefore, the scope of the invention should be determined by the appended claims.

Claims (10)

1. A bottle steering device, comprising: a blank turning track, the feeding end of the blank turning track is for communicating with a feeding end, and the discharge end of the blanking track is used for communicating to a bubble The hood or the bottle is conveyed on the track; the unloading turning track is arranged correspondingly to the shape of the bottle, and the unloading turning track is gradually twisted from the feeding end to the discharging end.
2. The bottle steering device according to claim 1, wherein the blank turning track is plural, and the plurality of blank turning rails are arranged side by side.
3. The bottle steering device according to claim 1, further comprising a reversing cutting mechanism, wherein the reversing cutting mechanism comprises a blanking plate, a limiting baffle, a switch plate and a first driving mechanism;

   The cutting opening is disposed on the blanking plate;

   The limiting baffle is located above the lowering plate, and one end of the limiting baffle projected on the lowering plate is located at an edge of the feeding opening, the limiting baffle and the lower There is a space between the plates, the interval size is larger than the outer diameter of the bottle head and smaller than the outer diameter of the bottle tail;

   The switch board is disposed corresponding to the cutting opening, and the first driving mechanism is configured to drive the switch board to move into or out of the feeding opening;

   When the limiting baffle abuts the bottle head, the bottle tail is completely above the switch plate; when the limit baffle abuts the bottle tail, a part of the bottle head is convex Out of the feed opening and above the lowering plate.
4. The bottle steering device according to claim 3, further comprising a partitioning mechanism disposed above the lowering plate, and the partitioning mechanism is slidably engaged with the lowering plate, The partitioning mechanism includes a plurality of first partitioning blocks arranged in parallel at intervals, an interval between adjacent ones of the first partitioning blocks can be used for the bottle to pass through; the lowering plate is provided with an opening area, the switch There are a plurality of plates, and the switch plate and the limiting baffle are respectively adjacent to the adjacent first blocking block Correspondingly, the switch plates are arranged side by side in the open area, the switch board is connected to the lower material board, and the lower feed opening is located between adjacent switch boards.
5. A bottle steering apparatus according to claim 4, further comprising a blanking partitioning plate, said blanking partitioning plate being disposed below said lowering plate, said blanking dividing plate comprising juxtaposed spacing a plurality of blanking chutes are disposed, and the unloading chutes correspond to the intervals between adjacent ones of the first separating blocks.
6. The bottle steering device according to claim 4, further comprising a carrier plate and a transport bottle mechanism, wherein the carrier plate is juxtaposed with a plurality of chutes for the bottle to slide over, the chute and the first The spacing between the spaced apart stops is used to drive the bottles in the chute to the blanking plate.
7. A bottle steering apparatus according to claim 6, further comprising a vibration mechanism coupled to said carrier.
8. The bottle steering device according to claim 6, further comprising a first side fence and a second side fence, wherein the first side fence and the second side fence are respectively disposed on the load On both sides of the board.
9. The bottle steering device according to claim 8, further comprising a first end stop and a second end stop, wherein the first end stop is disposed at a bottle output end of the carrier, a distance between a bottom surface of the one end baffle and a bottom wall of the chute is smaller than a height of the bottle; the second end baffle is disposed on the carrier, and the second end baffle and the first The one end baffle is disposed opposite to each other, and the first end baffle, the second end baffle, the first side baffle and the second side baffle enclose a silo.
10. A bottle steering device according to claim 6, further comprising a bottle position control mechanism, said bottle position control mechanism comprising a support plate, a switching partition and a second drive mechanism, said support plate being disposed at said load Between the plate and the partitioning mechanism, the switching partition and the support a sliding fit of the plate, the switching partitions are juxtaposed with a plurality of passages, the passages are correspondingly arranged with the sliding slots; the second driving mechanism is configured to drive the switching partitions to move to the first position or the second position And when the second driving mechanism drives the switching partition to move to the first position, the channel communicates with the sliding slot, and the interval between the channel and the adjacent first separating block Disconnecting; when the second driving mechanism drives the switching baffle to move to the second position, the channel is disconnected from the chute, and the channel is adjacent to the first separating block The interval between them is connected.

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